Abstract
The classification of “parasites” in the medical field is a challenging notion, a group which historically has included all eukaryotes exclusive of fungi that invade and derive resources from the human host. Since antiquity, humans have been identifying and documenting parasitic infections, and this collective catalog of parasitic agents has expanded considerably with technology. As our understanding of species boundaries and the use of molecular tools has evolved, so has our concept of the taxonomy of human parasites. Consequently, new species have been recognized while others have been relegated to synonyms. On the other hand, the decline of expertise in classical parasitology and limited curricula have led to a loss of awareness of many rarely encountered species. Here, we provide a comprehensive checklist of all reported eukaryotic organisms (excluding fungi and allied taxa) parasitizing humans resulting in 274 genus-group taxa and 848 species-group taxa. For each species, or genus where indicated, a concise summary of geographic distribution, natural hosts, route of transmission and site within human host, and vectored pathogens are presented. Ubiquitous, human-adapted species as well as very rare, incidental zoonotic organisms are discussed in this annotated checklist. We also provide a list of 79 excluded genera and species that have been previously reported as human parasites but are not believed to be true human parasites or represent misidentifications or taxonomic changes.
Keywords: Acanthocephalans, arthropods, cestodes, leeches, nematodes, parasitology, protozoa, trematodes
Introduction
The online Oxford English dictionary defines a parasite as: ‘an organism that lives in or on an organism of another species (its host) and benefits by deriving nutrients at the other’s expense’ (LEXICO 2020). From a strictly biological perspective, this definition can cover a wide variety of organisms, including, but not limited to, bacteria, viruses, fungi, helminths (worms), protozoans, cnidarians, tardigrades, rotifers, mollusks, and arthropods. However, in the historical concept of the medical community, the term ‘parasite’ refers to animals and other eukaryotic organisms with animal-like affinities, and is usually limited to the protozoans, helminths, and arthropods.
Historically, human parasites have been classified within the broad Linnaean kingdom of ‘Animals’ and divided into taxa with formal categorical names (phylum, class, order, family, etc.). While traditional Linnaean taxa are still commonly used for helminths and arthropods, it is becoming more common to use clade-based systems devoid of formal designations, especially with the taxa collectively called protozoans. Much of this work comes from a better understanding of the evolutionary relationships of organisms based on both morphological and molecular analyses (Adl and Mathison 2019).
Currently, eukaryotes are classified into two domains, Amorphea and Diaphoretickes, as well as additional large clades that do not fit into either of those domains. Within domains are large clades commonly referred to as supergroups. Eukaryotic parasitic organisms fall into five supergroups within these domains: SAR, Archaeplastida, Excavates, Amoebozoa, and Opisthokonta (Adl et al. 2019; Adl and Mathison 2019). For the purpose of this work, the focus is on the traditional human parasitic protozoans (Amoebozoa, SAR, Excavates) and helminths, annelids, and arthropods (all in Opisthokonta). Two groups of organisms that were historically considered protozoans, but are now considered fungi and are not included here, are Pneumocystisjirovecii Frenkel, 1999 (syn. P.carinii f. sp. hominis) and the microsporidia. The genus Prototheca is another opportunistically parasitic eukaryote, but is currently aligned with the algae in the clade Archaeplastida and is also not covered here (Lass-Flörl and Mayr 2007). For detailed descriptions on the higher classifications of eukaryotes, the readers are referred to the work by Adl and colleagues (Adl et al. 2019).
The Amoebozoa include many of the human parasites historically referred to as amebae, including the intestinal amebae Entamoeba, Endolimax, and Iodamoeba, and several of the ‘free-living’ amebae such as Balamuthia and Acanthamoeba (Adl and Mathison 2019). These organisms feed by phagocytosis and move by pseudopods. They lack cilia and most have an environmentally hardy stage (cyst) for dispersal and infection of a new host (Adl et al. 2019; Adl and Mathison 2019). The free-living amebae are not adapted for true parasitism and are only opportunistic parasites when conditions allow for colonization of the human host. Clinically, Acanthamoeba species are usually characterized by their genotypes rather than traditional Linnaean binominal nomenclature (Booton et al. 2005).
The SAR (which commonly refers to Stramenopiles-Alveolates-Rhizaria) includes parasitic coccidians (e.g., Toxoplasma, Cyclospora, Cystoisospora), gregarines (Cryptosporidium), piroplasmids (Babesia), haemosporidians (Plasmodium), ciliophores (Balantioides, formerly Balantidium), and the stremenopile Blastocystis (Adl and Mathison 2019).
Within the SAR, the coccidians, gregarines, piroplasmids, and hemosporidians are obligate parasites and part of the clade Apicomplexa that are characterized by a structure called an apical complex that is used for penetration of the host cell. Motility is usually by gliding or body flexion and feeding is by pinocystosis (ingestion by budding of small vesicles from the cell membrane). Apicomplexans may have one or two hosts and reproduce by sexual reproduction, the end result of which is an oocyst that when mature contains sporozoites that are the infectious stage for a new host (Adl et al. 2019; Adl and Mathison 2019). The Haemospororida (e.g., Plasmodium) and Piroplasmorida (e.g., Babesia) are vectored by sanguinivorous arthropods. Humans are intermediate hosts for Plasmodium, which are vectored by mosquitoes that serve as the definitive hosts. Babesia are zoonotic in humans and in nature typically cycle between a tick vector (definitive host) and a mammalian intermediate host (Adl and Mathison 2019).
The only human parasitic ‘ciliate’ is Balantioides (formerly Balantidium, syn. Neobalantidium). Movement is by numerous cilia and feeding is by phagocytosis. It forms an environmentally-hardy cyst that is the infectious stage for a new host (Adl et al. 2019; Adl and Mathison 2019).
Blastocystis is an enigmatic organism that has historically been variably classified among coccidians, fungi, and algae. The life cycle is still not completely understood, but it has been proposed that it reproduces by binary fission of vacuolar forms within the host and infects a new host via environmentally hardy cysts. Both vacuolar forms and cysts can be detected in stool specimens, and the variability in morphology of the former has created numerous descriptive terms. It has also been suggested it has a third form, an amoeboid form, that is responsible for pathogenesis in the host, but this hypothesis is not yet broadly accepted (Tan 2008). As the molecular epidemiology is becoming better understood, it is becoming less common to recognize Blastocystis by traditional Linnaean binominal nomenclature and more common to base identification on their genetic subtypes (Stensvold et al. 2007; Tan 2008).
The Excavates includes the traditional ‘flagellates’, such as Giardia, Trypanosoma, Dientamoeba, Chilomastix, Leishmania, and Trichomonas, as well as amoeboflagellates, such as Naegleria (Adl and Mathison 2019). All excavates move by cilia (historically referred to as flagella, which are not analogous to the bacterial flagellum) at some point in their life cycles. Most feed by pinocytosis (although the ameboid form of Naegleria and its relatives feed by phagocytosis). The life cycle patterns vary greatly among the excavates. Intestinal flagellates typically multiply by binary fission in the lumen of the intestine of their hosts and have an environmentally hardy cyst stage that is infectious for a new host. The trichomonads lack a cyst stage, and Dientamoeba is unusual in that it lacks external cilia and moves by pseudopods and feeds by phagocytosis, much like the Amoebozoa. The ‘hematoflagellates’ (Leishmania, Trypanosoma, Crithidia, Endotrypanum) have two host life cycles and are transmitted to the human host via an arthropod vector. Amoeboflagellates, such as Naegleria, Paravahlkampfia, Tetramitus, Vahlkampfia, Allovahlkampfia are not true parasites and only infect the human host when opportunities allow for infection and colonization (Adl et al. 2019; Adl and Mathison 2019).
The Opisthokonta includes the arthropods, leeches, and helminths, all within the clade Metazoa (Adl and Mathison 2019). The term ‘helminth’ is not a taxonomic unit in any classification scheme, but instead a basket term for parasitic worms of humans, which is divided into four broad categories: cestodes (tapeworms), trematodes (flukes), nematodes (roundworms), and acanthocephalans (thorny-headed worms) (Adl and Mathison 2019). Leeches (Annelida), while not historically considered helminths are blood-feeding animals that will opportunistically feed on humans. Within the Metazoa are the Spiralia (acanthocephalans, annelids, cestodes, trematodes) and Ecdysozoa (arthropods and nematodes).
The cestodes are obligate parasites that usually reside in the small intestine of their definitive host. Most have multiple-host life cycles, and the definitive host becomes infected after ingestion of a larval stage encysted in the tissues of an intermediate host. Adults are long, ribbon-like organisms that have three main body regions: scolex (for attachment to the intestinal mucosa of the definitive host), neck (the base of the strobila), and the strobila (the main body, which is made of up individual segments called proglottids). Historically, cestodes that parasitize humans were divided into two categories: Pseudophyllidea (Dibothriocephalus, Adenocephalus, Diphyllobothrium), and Cyclophyllidea (Taenia, Dipylidium, Hymenolepis, several others). However, Pseudophyllidea has been abandoned in favor of two broad groups, Bothriocephalidea and Diphyllobothriidea, the latter of which contains human parasites (Kuchta et al. 2008). From the perspective of species that parasitize humans, Diphyllobothriidea are characterized by adult worms that attach to the intestine of the definitive host by means of bothria (grooves in the scolex). Eggs have an operculum and are unembryonated when shed in feces, and the infectious stage for the definitive host is the plerocercoid larva (e.g., sparganum). The Cyclophyllidea however attach to the intestine of their definitive hosts by means of four suckers and (often) a rostellum, that may be armed with hooklets or not. Eggs lack an operculum, are shed embryonated, and contain a hooked oncosphere that is immediately infectious for an intermediate host. The infectious larva is highly variable and terminology is often taxon-dependent (cysticercus, hydatid cyst, tetrathyridium, etc.) (Chervy 2002; Adl and Mathison 2019).
The trematodes that infect humans are all within Digenea and are also obligate parasites with multi-host life cycles. All parasitic species of humans have a snail as a first intermediate host, and many digeneans have second intermediate hosts or paratenic hosts that may comprise a variety of animals; in some species, infective stages are encysted in the environment, including on the surface of plants. Adults are usually hermaphroditic, apart from the schistosomes which are dioecious but live in copula. Adults have two muscular suckers, an oral sucker for attachment and feeding and a ventral sucker (acetabulum) for attachment. Infection of the human host is either by direct penetration of the cercaria larval stage (Schistosoma) or ingestion of the metacercaria larval stage in an intermediate animal host or on contaminated plants (Adl and Mathison 2019).
The acanthocephalans are zoonotic parasites in humans. While superficially similar to nematodes, they are more closely related to the rotifers, or possibly nested within Rotifera, proper (Garcia-Varela et al. 2000). Adults are large, pseudocoelomate animals that attach to the intestinal mucosa of the definitive host be means of a heavily armed proboscis. Human infection usually occurs from the ingestion of an infected intermediate or paratenic host (Mathison et al. 2016). The leeches (Annelida: Hirudinea) include blood-feeding members that will opportunistically feed on humans. Most are aquatic and attacks on humans usually come from swimming, fishing, and wading in fresh water.
The nematodes are a large and diverse group of organisms, most of which are free-living, although some major parasitic lineages are of great public health importance. Despite their diversity in nature, few species parasitize humans with any regularity. Two major clades of human parasites are Dorylaimia and Chromadoria, which vary greatly in their biology, route of transmission, and morphology. Most nematodes have six developmental stages: egg, four larval stages (L1-L4), and adult (L5); some larviparous species do not lay eggs. For most parasitic nematodes of humans, the infectious stage is the L3 larva, this fact is often called the ‘Rule of the Infective Third State’. Notable exceptions are members of the Trichinellida, for which the infectious stage is the L1 larva, and Eustrongylides for which the infectious stage is believed to be the precocious L4 (Anderson 2000). Most intestinal nematodes infect the human host after ingestion of fully embryonated eggs in food, water, or fomites contaminated with feces, or after ingestion of an infected intermediate or paratenic host. L3 larvae of some species, such as Strongyloides and the hookworms, can penetrate intact human skin during walking on contaminated soil. Filarial nematodes (Spirudida: Filarioidea) are vectored by sanguinivorous arthropods (Ash and Orihel 2007; Adl and Mathison 2019; Carroll et al. 2019).
The arthropods are the largest group of Metazoa, but relatively few species are adapted to parasitism on humans. Two main clades are the Chelicerata and Mandibulata, which can be broadly separated by the structure of their mouthparts. The Chelicerata includes the mites and ticks. The Mandibulata includes Pancrustacea, which contains the clades Crustacea (crustaceans) and Hexapoda (insects). The only parasitic crustaceans of humans are zoonotic pentastomids (tongueworms). The pancrustacean clade Hexapoda includes parasitic insects such as lice, fleas, beg bugs, triatomine (kissing) bugs, and myiasis-causing flies. Arthropods are characterized by a jointed exoskeleton containing chitin. Development is variable and can be gradual (hemimetabolous) or complete (holometabolous). Holometabolous insects have morphologically and biologically markedly different life cycles stages including larvae, pupae, and adults (Mathison and Pritt 2014; Mathison and Pritt 2015; Adl and Mathison 2019).
Here we provide an updated checklist of the parasitic protozoans, helminths, annelids, and arthropods of humans, nearly 20 years since the last such endeavor (Ashford and Crewe 2003), while providing an updated higher taxonomy based on advances in eukaryotic taxonomy (Adl et al. 2019). Taxonomy and systematics are largely ignored in the education of medical and public health professionals. There are frequent updates to taxonomic changes in Medical Parasitology (Simner 2017; Adl and Mathison 2019; Mathison and Pritt 2019; Mathison and Pritt 2020; Mathison et al. 2021), but taxonomy remains a challenging discipline in the medical and public health realms. We also provide annotations on the geographic distribution, host range, route of infection, and anatomic site of infection for human eukaryotic parasites.
Materials and methods
The bulk of this manuscript is an annotated checklist of protozoan, helminthic, annelid, and arthropod parasites reported from the human host, based on extensive literature searches through April 2021. A systematic literature search of the PubMed database (U.S. National Library of Medicine National Institutes of Health; https://www.ncbi.nlm.nih.gov/pubmed), Google Scholar (https://scholar.google.com/) and Google (https://www.google.com) was also performed using the keyword search phrases using various taxa in combination with human infection and case reports. We aimed to include all protozoan and helminthic parasites known to be reported from humans. The leeches and arthropods, however, provided a special challenge, as an exhaustive list of every sanguinivorous species that may feed on a human host would be large and beyond the scope of the audience. For the arthropods, the focus is on ectoparasites that spend prolonged time on the human host (lice, sarcoptid and demodecid mites, hard ticks, myiasis-causing flies, Tunga fleas) and visceral parasites (pentastomids). For leeches and arthropods that are short-term blood feeders or biters, such as non-Tunga fleas, soft ticks, zoonotic biting mites, bed bugs, and triatomine bugs, the focus is on those species that are commonly associated with humans and/or vector medically-important pathogens. Sanguinivorous flies (mosquitoes, black flies, deer flies, etc.) are not included, nor are those flies and other insects (e.g., cockroaches) that may passively transmit pathogens. Arthropods that are considered medically important due to envenomation, stings, or urticarial and allergic reactions are also not included.
Suprageneric taxa are listed in a hierarchal system lacking formal designations, following Adl et al. (Adl et al. 2019). Each suprageneric taxon in indicated by a series of icons (●) rather than using traditional Linnaean categories such as order, family, etc. Each taxon has one more icon than the preceding taxon in which it belongs. The number of clades presented varies based on the diversity within a given clade in relation to human parasites.
For organisms traditionally classified as protozoans (Amoebozoa, Excavates, and SAR), clades above the traditional ‘family’ level follow Adl and colleagues (Adl et al. 2019). The family-group taxa (typically ending in -idae) are presented based on the current classifications of the given organisms. For the helminths and arthropods, the organisms considered ‘true’ animals (Opisthokonta), the classification follows Adl and colleagues (Adl et al. 2019) to the level Holozoa, after which clades follow the current classifications for the given organisms. Genera within a family-group taxon, and species within each genus, are presented alphabetically.
Species, and genera for which isolates from human cases have not been characterized at the species level, have at least four bullet-points of information: 1) Geographic distribution, 2) Natural hosts, 3) Route of infection, and 4) Site in/on human host. In addition, many of the arthropods and leeches also have an additional bullet-point, 5) Vectored pathogens.
Geographic distribution. This is the known geographic distribution of a given species or genus. For widespread organisms, the distribution is presented generally (e.g., Worldwide, North America, Circumtropical). For organisms that are more geographically restricted, the information is presented at the country level.
Natural hosts. These are the hosts that are part of the parasite’s natural life cycle. For multi-host parasites, the hosts are presented in developmental order, starting with the first intermediate host and finishing with the definitive host. Hosts for species or genera with broad host ranges are presented generally (e.g., mammals, carnivores, birds), while hosts for parasites that are more host specific are presented at a more granular level (e.g., mosquitoes in the genus Anopheles).
Route of infection. This is route through which the human host becomes infected or colonized.
Site in/on human host. This is where the parasite resides in the human host, and includes both the typical site as well as common sites of ectopic infection.
Vectored pathogens. This bullet-point is for all the arthropods, except for the pentastomids and most of the myiasis-causing fly larvae, and leeches. It provides information on infectious agents (bacteria, viruses, parasites) that are pathogenic for the human host that are transmitted by the given arthropod. It includes agents that are believed to be vectored by a given arthropod in a natural setting and does not include agents that have simply been detected in an arthropod using molecular surveillance or in experimental models.
For all taxonomic levels, select synonyms are presented, especially for names that show up frequently in the literature regarding human cases.
Lastly, a list of excluded species is presented. These are species that have been reported as human parasites but are either not believed to be true parasites in the human host, represent data based on misidentifications, or are invalid names. The excluded species are presented alphabetically.
Checklist of eukaryotic human parasites
Amoebozoa Lühe, 1913, amend Cavalier-Smith, 1998
● Tubulinea Smirnov et al., 2005
●● Echinamoebida Cavalier-Smith in Cavalier-Smith et al. 2004
Genus Vermamoeba Smirnov et al., 2011
Vermamoebavermiformis (Page, 1967)
Geographic distribution. Worldwide (Scheid 2019).
Natural host. None; occurs in natural freshwater environments, surface water, soil, and biofilms. Humans are incidental hosts (Scheid 2019; Scheid et al. 2019; Siddiqui et al. 2021).
Route of infection. Presumably environmental exposure into eyes, mucus membranes, and wounds (Abedkhojasteh et al. 2013; Scheid 2019; Scheid et al. 2019).
Site in human host. Skin and soft tissues, eye (Scheid et al. 2019).
Notes. Previous records of Harmannella from human clinical specimens probably refer to this species.
●● Elardia Kang et al., 2017
●●● Euamoebida Lepşi, 1960 sensu Smirnov et al., 2011
●●●● Hartmannellidae Volkonsky, 1931
Genus Hartmannella Alexeiff, 1912
Geographic distribution. Worldwide.
Natural host. None (environmental); humans are incidental hosts (Bradbury 2014).
Route of infection. Unknown; presumed environmental exposure and contamination (Bradbury 2014).
Site in human host. Intestinal tract (Bradbury 2014).
Notes. Most extraintestinal reports of human infection with Hartmanella apply to H.vermiformis Page, which is now in the genus Vermamoeba.
● Evosea Kang et al., 2017
●● Archamoeba Cavalier-Smith, 1993 sensu Cavalier-Smith et al., 2004
●●● Entamoebida Cavalier-Smith, 1993
●●●● Entamoebidae Chatton, 1925
Genus Endolimax Kuenen & Swellengrebel, 1913
Endolimaxnana (Wenyon et O’Connor, 1917)
Geographic distribution. Worldwide (Poulsen and Stensvold 2016).
Natural host. Humans (Poulsen and Stensvold 2016).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites(Poulsen and Stensvold 2016).
Site in human host. Large intestine, cecum, colon (Poulsen and Stensvold 2016).
Genus Entamoeba Casagrandi & Barbagallo, 1895
Entamoebabangladeshi Royer et al., 2012
Geographic distribution. Southeast Asia, sub-Saharan Africa (Hooshyar et al. 2015; Ngobeni et al. 2017).
Natural host. Humans (Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Entamoebacoli (Grassi, 1879)
Entamoebahominis Casagrandi & Barbagallo, 1897
Entamoebaloeschi Lesage, 1908
Councilmanialafleuri Kofoid & Swezy, 1921
Geographic distribution. Worldwide (Hooshyar et al. 2015).
Natural hosts. Humans, monkeys (Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Entamoebachattoni Swellengrebel, 1914
Geographic distribution. Africa (Verweij et al. 2001; Hooshyar et al. 2015).
Natural hosts. Non-human primates. Zoonotic in humans (Sargeaunt et al. 1992; Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Sargeaunt et al. 1992).
Site in human host. Large intestine, cecum, colon (Sargeaunt et al. 1992).
Entamoebadispar Brumpt, 1925
Geographic distribution. Worldwide (Ali 2015; Hooshyar et al. 2015).
Natural hosts. Humans, chimpanzee, baboons, macaques (Ali 2015; Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Entamoebagingivali s (Gros, 1849)
Amoebabuccalis Steinberg, 1862
Amoebadentalis Grassi, 1879
Amoebakartulis Doflein, 1901
Entamoebamaxillaris Kartulis, 1906
Entamoebacanibuccalis Smith, 1938
Endamoebaconfusa Craig, 1916
Entamoebaequibuccalis Simitch, 1938
Entamoebasuigingivalis Tumka, 1959
Geographic distribution. Worldwide (Hooshyar et al. 2015).
Natural hosts. Humans, horses, pigs, cats, monkeys (Hooshyar et al. 2015).
Route of infection. Person-to-person contact (Bonner et al. 2018; Bradbury et al. 2019b).
Site in human host. Oral cavity; ectopic colonization of urogenital tract (Cembranelli et al. 2013; Bonner et al. 2018; Bradbury et al. 2019b; Dubar et al. 2020).
Entamoebahartmanni Von Prowazek, 1912
Entamoebahistolytica, small race
Entamoebaminuta Woodcock & Penfold, 1916
Entamoebatenuis Kuenen & Swellengrebel, 1917
Entamoebaminutissima Brug, 1917
Geographic distribution. Worldwide (Hooshyar et al. 2015).
Natural host. Humans (Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Entamoebahistolytica Schaudinn, 1903
Amoebacoli Lösch, 1875
Amoebadysenteriae Councilman & Lafleur, 1891
Entamoebaafricana Hartmann & Von Prowazek, 1907
Entamoebaschaudinii Lesage, 1908
Entamoebaminuta Elmassian, 1909
Entamoebanipponica Koidzumi, 1909
Entamoebabrasiliensis Aragao, 1912
Entamoebavenaticum Darling, 1915
Entamoebacaudata Carini & Reichenow, 1949
Geographic distribution. Worldwide; endemic areas of clinical amebiasis include Central and South America, Africa, Southeast Asia (Ali 2015; Shirley et al. 2018).
Natural host. Humans (Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites; oral-anal sex (Shirley et al. 2018).
Site in human host. Large intestine, cecum, colon; ectopic colonization of liver, skin, lungs, brain (Ali 2015; Mathison and Pritt 2018; Shirley et al. 2018).
Entamoebamoshkovskii (Tshalaia, 1941)
Entamoebahistolytica, Laredo strain
Entamoebahistolytica, Huff strain
Geographic distribution. Presumed worldwide; high areas of endemicity include Australia, India, Bangladesh, Tanzania, Pakistan, Iran (Ali 2015; Kyany’a et al. 2019).
Natural host. Humans (Hooshyar et al. 2015; Lopez et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Entamoebanuttalli (Castellani, 1908)
Loeschiaduboscqi Mathis, 1913
Amoebaateles Eichhorn & Gallagher, 1916
Loeschiacynomolgi Brug, 1923
Geographic distribution. Native to Southeast Asia, probably worldwide in zoos and from the animal trade (Tanaka et al. 2019).
Natural hosts. Non-human primates. Zoonotic in humans (Hooshyar et al. 2015; Levecke et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites.
Site in human host. Large intestine, cecum, colon (Levecke et al. 2015)
Entamoebapolecki (Von Prowazek, 1912)
Entamoebadebliecki Nieschulz, 1923
Geographic distribution. Worldwide; spots of high endemicity include Venezuela, Iran, Southeast Asia, Papua New Guinea (Verweij et al. 2001; Stensvold et al. 2018).
Natural hosts. Pigs, monkeys. Zoonotic in humans (Hooshyar et al. 2015).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ali 2015).
Site in human host. Large intestine, cecum, colon (Ali 2015).
Genus Iodamoeba Dobell, 1919
Iodamoebabuetschlii (Von Prowazek, 1912)
Geographic distribution. Worldwide (Ash and Orihel 2007).
Natural host. Human (Ash and Orihel 2007).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Ash and Orihel 2007).
Site in human host. Large intestine, cecum, colon (Ash and Orihel 2007).
● Discosea Cavalier-Smith et al., 2004
●● Flabellinia Smirnov et al., 2005
●●● Thecamoebida Schaeffer, 1926, emend. Smirnov et al., 2011
●●●● Thecamoebidae Schaeffer, 1926, emend. Smirnov et al., 2011
Genus Sappinia Dangeard, 1896
Sappiniapedata Dangeard, 1896
Geographic distribution. Presumed worldwide (Visvesvara 2013).
Natural host. None (environmental); humans are incidental hosts
Route of infection. Presumably by the entry of cysts or trophozoites through mucous membranes (e.g., nasal passages) or broken skin (Qvarnstrom et al. 2009; Visvesvara 2013).
Site in human host. Central nervous system (CNS) (Qvarnstrom et al. 2009; Visvesvara 2013).
●● Centramoebia Cavalier-Smith et al., 2016
●●● Acanthopodida Page, 1976
●●●● Acanthamoebidae Sawyer & Griffin, 1975
Genus Acanthamoeba Volonsky, 1931
Notes. Clinically, Acanthamoeba species are usually characterized by their genotypes rather than traditional Linnaean binominal nomenclature (Booton et al. 2005).
Acanthamoeba Genotype T1
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) or broken skin (Booton et al. 2005; Khan 2006).
Site in human host. CNS (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T2
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Booton et al. 2005; Khan 2006).
Site in human host. Eye (Khan 2006).
Acanthamoeba Genotype T3
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Booton et al. 2005; Khan 2006).
Site in human host. Eye (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T4
Geographic distribution. Worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) or broken skin (Booton et al. 2005; Khan 2006).
Site in human host. Eye, skin, lung, brain, sinus cavity, disseminated infection (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T5
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Ledee et al. 2009).
Site in human host. Eye (Ledee et al. 2009).
Acanthamoeba Genotype T6
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Booton et al. 2005; Khan 2006).
Site in human host. Eye (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T8
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Orosz et al. 2018).
Site in human host. Eye (Orosz et al. 2018).
Acanthamoeba Genotype T10
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) or broken skin (Booton et al. 2005; Khan 2006; Nuprasert et al. 2010).
Site in human host. CNS, eye (Booton et al. 2005; Khan 2006; Nuprasert et al. 2010).
Acanthamoeba Genotype T11
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Booton et al. 2005; Khan 2006).
Site in human host. Eye (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T12
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) or broken skin (Booton et al. 2005; Khan 2006).
Site in human host. CNS (Booton et al. 2005; Khan 2006).
Acanthamoeba Genotype T13
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Grün et al. 2014)
Site in human host. Eye (Grün et al. 2014).
Acanthamoeba Genotype T15
Geographic distribution. Presumed worldwide (Booton et al. 2005).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) (Di Cave et al. 2009).
Site in human host. Eye (Di Cave et al. 2009).
●●●● Balamuthiidae Cavalier-Smith et al., 2004
Genus Balamuthia Visvesvara et al., 1993
Balamuthiamandrillaris Visvesvara et al., 1993
Geographic distribution. Worldwide (Visvesvara 2013; Cope et al. 2019).
Natural host. None (environmental); humans are incidental hosts.
Route of infection. Entry of environmental trophozoites or cysts through mucous membranes (e.g., eye, nasal passages) or broken skin (Visvesvara 2013; Cope et al. 2019).
Site in human host. Disseminated infection with predilection for CNS (Visvesvara 2013; Cope et al. 2019).
SAR (Stremanopiles-Alveolata-Rhizaria) Burki et al., 2008, emend. Adl et al., 2012
● Stramenopiles Patterson 1989, emend. Adl et al., 2005
●● Bigyra Cavalier-Smith, 1998, emend. Cavalier-Smith et al., 2006
●●● Opalozoa Cavalier-Smith, 1991, emend. Cavalier-Smith et al., 2006
●●●● Opalinata Wenyon, 1926, emend. Cavalier-Smith, 1997
Genus Blastocystis Alexeieff, 1911
Notes. As the molecular epidemiology is becoming better understood, it is becoming less common to recognize Blastocystis by traditional Linnaean binominal nomenclature but rather by their genetic subtypes (Stensvold et al. 2007; Tan 2008).
Blastocystis subtype 1
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Various mammals. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 2
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Non-human primates, pigs. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 3
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 4
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Rodents. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 5
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Pigs, cattle. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 6
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Birds. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 7
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Birds. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 8
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Monkeys, birds. Zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 9
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Unknown; presumed zoonotic in humans (Stensvold et al. 2007; Tan 2008).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
Blastocystis subtype 12
Geographic distribution. Worldwide (Stensvold et al. 2007; Tan 2008).
Natural hosts. Goats, cattle. Zoonotic in humans (Stensvold et al. 2007; Tan 2008; Udonsom et al. 2018; Jiménez et al. 2019).
Route of infection. Ingestion of cyst-forms and/or vacuolar-forms in contaminated food, water, fomites (Tan 2008).
Site in human host. Large intestine (Tan 2008).
● Alveolata Cavalier-Smith, 1991
●● Colpodellida Cavalier-Smith, 1993, amend. Adel et al. 2005, 2019
●●● Colpodellidae Simpson & Patterson, 1996
Genus Colpodella Cienkowski, 1865
Geographic distribution. Worldwide (Getty et al. 2021).
Natural hosts. None; free-living predators of other protozoans. Humans are incidental hosts (Getty et al. 2021).
Route of infection. Unknown, proposed transmission via the bite of ticks in the genus Ixodes (Yuan et al. 2012; Jiang et al. 2018).
Site in human host. Blood (Yuan et al. 2012; Jiang et al. 2018).
Notes. In nature, Colpodella species are free-living predators of other protozoans. Copodella-like organisms have been diagnosed twice in patients from China, one from blood (Yuan et al. 2012) and once from CSF (Jiang et al. 2018); only the former also demonstrated morphologic evidence of a potential parasite. In both cases, the identifications were made by sequencing analyses. The species-level identification was not made in either case, and the organisms in at least one of the cases (Yuan et al. 2012) might represent an as-of-yet undescribed genus. Further work is needed to confirm the ability of Colpodella and related organisms to cause parasitic infections in humans.
●● Apicomplexa Levine, 1970, emend. Adl et al. 2005
●●● Aconoidasida Mehlhorn et al., 1980
Hematazoa Vivier, 1982
●●●● Haemospororida Danilewsky, 1885
●●●●● Plasmodiidae Mesnil, 1903
Genus Plasmodium Marchiafava & Celli, 1885
Plasmodiumbrasilianum Gonder et von Berenberg-Gossler, 1908
Geographic distribution. Brazil, Venezuela, Colombia , Panama, Peru (Coatney et al. 1971).
Natural hosts. Intermediate hosts are New World monkeys. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as an intermediate host (Coatney et al. 1971; Lalremruata et al. 2015).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection), blood (Coatney et al. 1971).
Notes. It has been suggested that P.brasilianum is conspecific with P.malariae and that P.malariae adapted to non-human primates in Latin America after being introduced from Africa (Guimaraes et al. 2012).
Plasmodiumcoatneyi Eyles et al., 1962
Geographic distribution. Peninsular Malaysia, Philippines (Coatney et al. 1971).
Natural hosts. Intermediate host is the crab-eating macaque (Macacafascicularis). Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as an intermediate host (Coatney et al. 1971; Yap et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection), blood (Coatney et al. 1971).
Plasmodiumcynomolgi Mayer, 1907
Geographic distribution. Southeast Asia (Coatney et al. 1971).
Natural hosts. Intermediate hosts are macaques. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as an intermediate host (Coatney et al. 1971; Hartmeyer et al. 2019; Yap et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection, chronic sequestration), blood (Coatney et al. 1971).
Plasmodiumfalciparum (Welch, 1897)
Oscillariamalariae Laveran, 1881
Haemamoebapraecox Feletti & Grassi, 1890
Haemamoebaimmaculata Grassi, 1891
Haemamoebalaverani Labbe, 1894
Haemosporidiumsedecimanae Lewkowicz, 1897
Haemosporidiumvigesimotertianae Lewkowicz, 1897
Geographic distribution. Circumtropical; sub-Saharan Africa, Asia, Latin America, Caribbean (Snow et al. 2005; Weiss et al. 2019).
Natural hosts. Intermediate hosts are humans. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles (Coatney et al. 1971).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection), blood, CNS (cerebral malaria) (Coatney et al. 1971; Idro et al. 2010).
Plasmodiuminui Helberstaedter & Von Prowazek, 1907
Geographic distribution. Southeast Asia (Coatney et al. 1971).
Natural hosts. Intermediate hosts are Old World monkeys. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as an intermediate host (Coatney et al. 1971; Yap et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection), blood (Coatney et al. 1971; Liew et al. 2021).
Plasmodiumknowlesi Sinton & Mulligan, 1932
Geographic distribution. Southeast Asia (Coatney et al. 1971).
Natural hosts. Intermediate hosts are macaques. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as an intermediate host (Coatney et al. 1971; Singh and Daneshvar 2013; Yap et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection), blood (Coatney et al. 1971).
Plasmodiummalariae (Grassi & Feletti, 1890)
Plasmodiumquartanae Celli & Sanfelice, 1891
Haematosporidiumtertianae Labbe, 1894
Geographic distribution. Sub-Saharan Africa, Southeast Asia, Indonesia, Pacific Islands, Amazonian South America (Coatney et al. 1971; Collins and Jeffery 2007).
Natural hosts. Intermediate hosts are humans; non-human primates in Latin America are reservoir hosts. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles (Coatney et al. 1971; Collins and Jeffery 2007).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971; Collins and Jeffery 2007).
Site in human host. Liver (initial infection), blood (Coatney et al. 1971; Collins and Jeffery 2007).
Plasmodiumovalecurtisi Sutherland et al., 2010
Geographic distribution. Western sub-Saharan Africa, Southeast Asia (Coatney et al. 1971).
Natural hosts. Intermediate hosts are humans. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles (Coatney et al. 1971; Collins and Jeffery 2005; Oguike et al. 2011).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971; Collins and Jeffery 2005).
Site in human host. Liver (initial infection, chronic sequestration), blood (Coatney et al. 1971; Collins and Jeffery 2005).
Notes. With the separation of P.ovale into the subspecies P.ovalecurtisi and P.o.wallikeri, the epidemiology of the two species in not well understood. Both subspecies are sympatric at the country level in several African countries, but their individual distributions in Southeast Asia are not well defined (Oguike et al. 2011).
Plasmodiumovalewallikeri Sutherland et al., 2010
Geographic distribution. Western sub-Saharan Africa, Southeast Asia (Coatney et al. 1971).
Natural hosts. Intermediate hosts are humans. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles (Coatney et al. 1971; Collins and Jeffery 2005; Oguike et al. 2011).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971; Collins and Jeffery 2005).
Site in human host. Liver (initial infection, chronic sequestration), blood (Coatney et al. 1971; Collins and Jeffery 2005).
Notes. With the separation of P.ovale into the subspecies P.ovalecurtisi and P.o.wallikeri, the epidemiology of the two species in not well understood. Both subspecies are sympatric at the country level in several African countries, but their individual distributions in Southeast Asia are not well defined (Oguike et al. 2011).
Plasmodiumschwetzi Brumpt, 1938
Geographic distribution. Tropical Africa (Coatney et al. 1971).
Natural hosts. Intermediate hosts are gorillas and chimpanzees. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as intermediate hosts (Contacos et al. 1970; Coatney et al. 1971).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection, presumed chronic sequestration), blood (Coatney et al. 1971).
Plasmodiumsimiovale Dissanaike, Nelson & Garnham, 1965
Geographic distribution. Sri Lanka, Malaysia (Coatney et al. 1971).
Natural hosts. Intermediate hosts is the toque macaque (Macacasinica). Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as intermediate hosts (Coatney et al. 1971; Yap et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection, chronic sequestration), blood (Coatney et al. 1971; Yap et al. 2021).
Plasmodiumsimium Fonseca, 1951
Geographic distribution. Brazil (Coatney et al. 1971).
Natural hosts. Intermediate hosts are howler monkeys and capuchins. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles. Zoonotic in humans as intermediate hosts (Coatney et al. 1971; Brasil et al. 2017).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection, chronic sequestration), blood (Coatney et al. 1971; Brasil et al. 2017).
Notes. It has been suggested P.simium is conspecific with P.vivax, and that P.vivax adapted to non-human primates in Latin America after being introduced by humans (Daron et al. 2020).
Plasmodiumvivax (Grassi & Feletii, 1890)
Haemamoebamalariae Feletti & Grassi, 1890, in part
Haemosporidiumtertianae Lewkowicz, 1897
Plasmodiumcamarense Ziemann, 1915
Geographic distribution. Africa (east, Horn of Africa, and Madagascar), Central and South America, Central Asia, Indian Subcontinent, Southeast Asia, Korean Peninsula (Coatney et al. 1971; Howes et al. 2016).
Natural hosts. Intermediate hosts are humans; non-human primates can serve as reservoir hosts. Arthropod vector and definitive hosts are mosquitoes in the genus Anopheles (Coatney et al. 1971).
Route of infection. Introduction of sporozoites via the bite of infected Anopheles mosquito (Coatney et al. 1971).
Site in human host. Liver (initial infection, chronic sequestration), blood, CNS (Coatney et al. 1971; Sarkar and Bhattacharya 2008; Mukhtar et al. 2019).
●●●● Piroplasmorida Wenyon, 1926
●●●●● Babesiidae Poche, 1913
Genus Babesia Starcovivi, 1893
Babesiadivergens M’Fadyean & Stockman, 1911
Geographic distribution. Europe (Ord and Lobo 2015)
Natural hosts. Intermediate hosts are primarily cattle. Arthropod vector and definitive hosts are ticks in the genus Ixodes, primarily I.ricinus. Zoonotic in humans as intermediate hosts (Ord and Lobo 2015; Kukina et al. 2018, 2019).
Route of infection. Introduction of sporozoites via the bite of the Ixodes tick vector; person-to-person transmission via blood and solid organ transplants (Ord and Lobo 2015; Kukina et al. 2018, 2019).
Site in human host. Blood (Ord and Lobo 2015; Kukina et al. 2018, 2019).
Babesiaduncani Conrad et al., 2006
Babesia strain WA1
Babesia strain WA2
Babesia strain CA5
Babesia strain CA6
Geographic distribution. Western and northern North America (Conrad et al. 2006; Ord and Lobo 2015).
Natural hosts. Intermediate hosts are suspected as being mule deer (Odocoileushemionus). Arthropod vector and definitive host is believed to be the tick Dermacentoralbipictus. Zoonotic in humans (Swei et al. 2019).
Route of infection. Introduction of sporozoites via the bite of the presumptive tick vector; possibly also via blood transfusion and solid organ transplants (Conrad et al. 2006).
Site in human host. Blood.
Babesiamicroti (França, 1910)
Geographic distribution. Northeastern North America, Australia (Senanayake et al. 2012; Ord and Lobo 2015; Westblade et al. 2017).
Natural hosts. Intermediate hosts are rodents, primarily white-footed mice (Peromyscusleucopus), and deer, primarily white-tailed deer (Odocoileusvirginianus). Arthropod vector and definitive hosts are ticks in the genus Ixodes, primarily I.scapularis. Zoonotic in humans as intermediate hosts (Westblade et al. 2017).
Route of infection. Introduction of sporozoites via the bite of infected tick, blood transfusion, and solid organ transplants (Ord and Lobo 2015; Westblade et al. 2017).
Site in human host. Blood (Ord and Lobo 2015; Westblade et al. 2017).
Babesiamotasi Wenyoun, 1926
Babesia sp. Strain KO-1
Babesiaovis-like
Geographic distribution. Eurasia (Kim et al. 2007; Hong et al. 2019).
Natural hosts. Intermediate hosts are sheep. Definitive hosts are ticks in the genus Haemaphysalis. Zoonotic in humans as intermediate hosts (Kim et al. 2007; Hong et al. 2019; Wang et al. 2020).
Route of infection. Introduction of sporozoites via the bite of infected tick (Kim et al. 2007; Hong et al. 2019; Wang et al. 2020).
Site in human host. Blood (Hong et al. 2019).
Babesiaodocoilei Emerson & Wright, 1970
Geographic distribution. Eastern North America (Pattullo et al. 2013).
Natural hosts. Intermediate hosts are cervids, primarily white-tailed deer (Odocoileusvirginianus). Arthropod vector and definitive host is the tick Ixodesscapularis; birds may serve as reservoir hosts for larvae or nymphs. Zoonotic in humans as intermediate hosts (Pattullo et al. 2013; Scott et al. 2021).
Route of infection. Introduction of sporozoites via the bite of infected tick (Scott et al. 2021).
Site in human host. Blood (Scott et al. 2021).
Babesiavenatorum Herwaldt et al., 2003
Babesia strain EU1
Geographic distribution. Europe (Herwaldt et al. 2003).
Natural hosts. Intermediate hosts are red deer (Cervuselaphus); roe deer, sheep, dogs, cats, and other mammals may serve as reservoir hosts. Arthropod vectors and definitive hosts are ticks in the genus Ixodes, primarily I.ricinus. Zoonotic in humans as intermediate hosts (Herwaldt et al. 2003; Gray et al. 2019).
Route of infection. Introduction of sporozoites via the bite of infected Ixodes tick; possibly also via blood transfusion and solid organ transplants (Herwaldt et al. 2003).
Site in human host. Blood (Herwaldt et al. 2003).
Babesia sp. Strain MO-1
Babesiadivergens-like
Geographic distribution. Central and Pacific Northwest USA (Burgess et al. 2017).
Natural hosts. Unknown; presumed intermediate hosts are unknown and presumed arthropod vector and definitive hosts are ticks in the genus Ixodes. Zoonotic in humans as intermediate hosts (Burgess et al. 2017; Herc et al. 2018).
Route of infection. Introduction of sporozoites via the bite of infected tick; possibly also via blood transfusion and solid organ transplantation (Burgess et al. 2017; Herc et al. 2018).
Site in human host. Blood (Burgess et al. 2017; Herc et al. 2018).
Notes. This strain was originally described from Missouri, USA. It has since been described from the states of Washington, Kentucky, and Arkansas (Burgess et al. 2017). Genetically it is very similar to the Palearctic B.divergens and is often referred to as Babesiadivergens-like (Herc et al. 2018).
Babesia sp. crassa -like
Geographic distribution. Undefined; human cases known from China and Slovenia (Jia et al. 2018; Strasek-Smrdel et al. 2020).
Natural hosts. Unknown; presumed intermediate hosts are sheep, goats, presumed arthropod vector and definitive hosts are ticks in the genera Haemaphysalis and/or Ixodes. Zoonotic in humans as intermediate hosts (Jia et al. 2018; Strasek-Smrdel et al. 2020).
Route of infection. Introduction of sporozoites via the bite of infected tick; possibly also via blood transfusion and solid organ transplantation (Jia et al. 2018; Strasek-Smrdel et al. 2020).
Site in human host. Blood (Jia et al. 2018; Strasek-Smrdel et al. 2020).
●●●●● Anthemosomatidae Levine, 1981
Genus Anthemosoma Landau et al., 1969
Anthemosomagarnhami Landau et al., 1969
Geographic distribution. Sub-Saharan Africa (Chavatte et al. 2018).
Natural hosts. Intermediate hosts are rodents, including spiny mice (Acomys). Arthropod vector and definitive hosts are unknown but presumed to be ixodid ticks. Zoonotic in humans (Chavatte et al. 2018; Stead et al. 2021).
Route of infection. Presumably by introduction of sporozoites via the bite of an infected tick (Stead et al. 2021).
Site in human host. Blood (Stead et al. 2021).
●●● Conoidasida Levine, 1988
●●●● Coccidia Leuckart, 1879
●●●●● Eimeriorina Léger, 1911
●●●●●● Eimeriidae Minchin, 1903
Genus Cyclospora Schneider, 1881
Cyclosporacayetanensis Ortega et al., 1994
Geographic distribution. Nearly worldwide, hot spots of endemicity include Latin America, the Caribbean, Middle East, and Southeast Asia (Ortega and Sanchez 2010; Almeria et al. 2019).
Natural host. Human (Ortega and Sanchez 2010; Almeria et al. 2019).
Route of infection. Ingestion of sporulated oocysts in fecally contaminated produce and water (Ortega and Sanchez 2010; Cama and Mathison 2015; Almeria et al. 2019).
Site in human host. Small intestine (Ortega and Sanchez 2010; Almeria et al. 2019).
●●●●●● Sarcocystidae Poche, 1913
Genus Cystoisospora Frenkel, 1977
Cystoisosporabelli (Wenyon, 1923)
Geographic distribution. Nearly worldwide, more prevalent in tropics and subtropics (Cama and Mathison 2015; Dubey and Almeria 2019).
Natural host. Human (Cama and Mathison 2015; Dubey and Almeria 2019).
Route of infection. Ingestion of sporulated oocysts in fecally contaminated water, food, fomites (Cama and Mathison 2015; Dubey and Almeria 2019)
Site in human host. Small intestine (Cama and Mathison 2015; Dubey and Almeria 2019; Rowan et al. 2020)
Genus Sarcocystis Lankester, 1882
Sarcocystisheydorni Dubey et al., 2015
Geographic distribution. Europe, China (Dubey et al. 2015).
Natural hosts. Cattle are intermediate hosts. Humans are the definitive hosts (Dubey 2015; Dubey et al. 2015).
Route of infection. Ingestion of cysts (bradyzoites) in undercooked beef (Dubey 2015; Dubey et al. 2015).
Site in human host. Small intestine (Dubey 2015; Dubey et al. 2015)
Sarcocystishominis (Railiet & Lucet, 1891)
Sarcocystisbovihominis Heydorn et al., 1975
Geographic distribution. Nearly worldwide, more prevalent in tropics and subtropics (Dubey 2015).
Natural hosts. Intermediate hosts are cattle. Definitive hosts are humans and non-human primates (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Route of infection. Ingestion of cysts (bradyzoites) in undercooked beef (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Site in human host. Small intestine (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Sarcocystisnesbitti Mandour, 1969
Geographic distribution. Southeast Asia (Abubakar et al. 2013; Fayer et al. 2015).
Natural hosts. Unknown. Natural intermediate host is unknown, non-human primates can serve as intermediate or reservoir hosts. Definitive hosts are presumed to be snakes or other reptiles. Zoonotic in humans as incidental intermediate hosts (Abubakar et al. 2013).
Route of infection. Ingestion of fully-sporulated oocysts in contaminated food, water, fomites (Abubakar et al. 2013; Fayer et al. 2015).
Site in human host. Skeletal muscle (Abubakar et al. 2013; Fayer et al. 2015).
Sarcocystissuihominis Heydorn, 1977
Geographic distribution. Nearly worldwide, more prevalent in tropics and subtropics (Dubey 2015).
Natural hosts. Intermediate hosts are pigs. Definitive hosts are humans and non-human primates (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Route of infection. Ingestion of cysts (bradyzoites) in undercooked pork (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Site in human host. Small intestine (Fayer 2004; Dubey 2015; Fayer et al. 2015).
Genus Toxoplasma Nicolle & Manceaux, 1909
Toxoplasmagondii (Nicolle & Manceaus, 1908)
Geographic distribution. Worldwide (Robert-Gangneux and Darde 2012).
Natural hosts. Wild and domestic felids. Many mammals and birds can serve as reservoir hosts; zoonotic in humans as dead-end hosts (Attias et al. 2020).
Route of infection. Ingestion of fully sporulated oocysts in food, water, fomites contaminated with cat feces; ingestion of cysts (bradyzoites) in infected paratenic hosts; blood transfusion or solid organ transplantation; transplacentally from mother to fetus (Montoya and Remington 2008; Robert-Gangneux and Darde 2012; Attias et al. 2020).
Site in human host. Disseminated infection, common sites are skeletal muscle, myocardium, brain, and eyes; can be transmitted transplacentally from mother to fetus (Montoya and Remington 2008; Robert-Gangneux and Darde 2012).
●●●● Gregarinasina Dufour, 1828
●●●●● Cryptogregarinorida Cavalier-Smith, 2014, emend. Adl et al., 2019
●●●●●● Cryptosporidiidae Leger, 1911
Genus Cryptosporidium Tyzzer, 1910
Cryptosporidiumandersoni Lindsay et al., 2000
Geographic distribution. Worldwide (Feng et al. 2011).
Natural hosts. Cattle, camels, sheep, goats, horses. Zoonotic in humans (Feng et al. 2011; Liu et al. 2015).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with animal feces (Jiang et al. 2014).
Site in human host. Unknown, presumed stomach.
Cryptosporidiumbovis Barker & Carbonell, 1974
Geographic distribution. Worldwide (Feng et al. 2007).
Natural hosts. Cattle. Zoonotic in humans (Ng et al. 2012; Das et al. 2019).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with cattle feces (Ng et al. 2012; Das et al. 2019).
Site in human host. Duodenum and small intestine.
Cryptosporidiumcanis Fayer et al., 2001
Geographic distribution. Worldwide (Fayer et al. 2001).
Natural hosts. Dogs. Zoonotic in humans (Fayer et al. 2001; Ryan et al. 2016).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with dog feces (Fayer et al. 2001; Ryan et al. 2016).
Site in human host. Duodenum and small intestine
Cryptosporidiumcuniculus Inman & Takeuchi, 1979
Geographic distribution. Undefined, most human cases from Europe and Australia (Koehler et al. 2014; Puleston et al. 2014).
Natural hosts. Rabbits, kangaroos. Zoonotic in humans (Koehler et al. 2014; Puleston et al. 2014).
Route of infection. Ingestion of sporulated oocysts water, food, fomites contaminated with rabbit/animal feces (Koehler et al. 2014; Puleston et al. 2014; Ryan et al. 2016).
Site in human host. Duodenum and small intestine.
Cryptosporidiumditrichi Čondlová et al., 2018
Geographic distribution. Europe (Condlova et al. 2018).
Natural hosts. Field mice (Apodemus spp.). Zoonotic in humans (Condlova et al. 2018; Beser et al. 2020).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with rodent feces (Beser et al. 2020; Condlova et al. 2018).
Site in human host. Duodenum and small intestine
Cryptosporidiumerinacei Kváč et al., 2014
Cryptosporidium hedgehog genotype
Geographic distribution. Europe (Kváč et al. 2014).
Natural hosts. Hedgehogs, horses. Zoonotic in humans (Kváč et al. 2014; Zahedi et al. 2016).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with animal feces (Kváč et al. 2014; Zahedi et al. 2016).
Site in human host. Duodenum and small intestine
Cryptosporidiumfayeri Ryan et al., 2008
Geographic distribution. Australia (Ryan et al. 2008; Waldron et al. 2010).
Natural hosts. Marsupials. Zoonotic in humans (Waldron et al. 2010).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with marsupial feces (Waldron et al. 2010).
Site in human host. Duodenum and small intestine
Cryptosporidiumfelis Iseki, 1979
Geographic distribution. Worldwide (Jiang et al. 2020).
Natural hosts. Cats, foxes, horses, cattle. Zoonotic in humans (Caccio et al. 2002; Jiang et al. 2020).
Route of infection. Ingestion of sporulated oocysts in fecally contaminated water, food, fomites contaminated with cat/animal feces (Caccio et al. 2002; Jiang et al. 2020).
Site in human host. Duodenum and small intestine
Cryptosporidiumhominis Morgan-Ryan et al., 2002
Geographic distribution. Worldwide (Cama and Mathison 2015).
Natural hosts. Humans, non-human primates (Cama and Mathison 2015; Ryan et al. 2016; Chen et al. 2019).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with human feces (Cama and Mathison 2015).
Site in human host. Duodenum and small intestine, disseminated infections in immunocompromised patients (Bouzid et al. 2013; Cama and Mathison 2015).
Cryptosporidiummeleagridis Slavin, 1955
Geographic distribution. Worldwide
Natural hosts. Birds. Zoonotic in humans (Akiyoshi et al. 2003).
Route of infection. Ingestion of sporulated oocysts in fecally contaminated water, food, fomites contaminated with bird feces (Akiyoshi et al. 2003).
Site in human host. Duodenum and small intestine, disseminated infections in immunocompromised patients (Akiyoshi et al. 2003; Kopacz et al. 2019).
Cryptosporidiummuris Tyzzer, 1910
Geographic distribution. Worldwide (Chappell et al. 2015).
Natural hosts. Rodents, ruminants, horses, non-human primates, carnivores. Zoonotic in humans (Chappell et al. 2015).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with animal feces (Chappell et al. 2015).
Site in human host. Unknown, presumed stomach (Chappell et al. 2015).
Cryptosporidiumoccultus Kváč et al., 2018
Cryptosporidiumparvum VF383
Geographic distribution. Worldwide (Kvac et al. 2018).
Natural hosts. Rodents. Zoonotic in humans (Kvac et al. 2018; Xu et al. 2020).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with rodent feces (Kvac et al. 2018; Xu et al. 2020).
Site in human host. Duodenum and small intestine
Cryptosporidiumparvum Tyzzer, 1912
Geographic distribution. Worldwide (Cama and Mathison 2015; Ryan et al. 2016).
Natural hosts. Cattle, sheep, goats, and other ruminants, rodents. Zoonotic in humans (Cama and Mathison 2015; Ryan et al. 2016).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with human and animal feces (Cama and Mathison 2015; Ryan et al. 2016).
Site in human host. Duodenum and small intestine, disseminated infections in immunocompromised patients (Cama and Mathison 2015; Ryan et al. 2016).
Cryptosporidiumryanae Fayer et al., 2008
Cryptosporidium deer-like genotype
Geographic distribution. XX (Fayer et al. 2008).
Natural hosts. Cattle. Zoonotic in humans (Chako et al. 2010; Das et al. 2019).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with cattle feces (Das et al. 2019).
Site in human host. Duodenum and small intestine.
Cryptosporidiumscrofarum Kváč et al., 2013
Cryptosporidium pig genotype II
Geographic distribution. Worldwide (Kváč et al. 2013).
Natural hosts. Pigs. Zoonotic in humans (Ryan et al. 2016).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with pig feces (Ryan et al. 2016).
Site in human host. Duodenum and small intestine.
Cryptosporidiumsuis Ryan et al., 2004
Geographic distribution. Worldwide (Ryan et al. 2004).
Natural hosts. Pigs. Zoonotic in humans (Xiao et al. 2002).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with pig feces (Xiao et al. 2002; Nemejc et al. 2013)
Site in human host. Duodenum and small intestine
Cryptosporidiumtyzzeri Ren et al., 2012
Cryptosporidium mouse genotype I
Geographic distribution. Presumed worldwide (Raskova et al. 2013).
Natural hosts. Rodents, horses may serve as reservoir hosts. Zoonotic in humans (Raskova et al. 2013; Wagnerová et al. 2015).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with rodent feces (Raskova et al. 2013).
Site in human host. Duodenum and small intestine
Cryptosporidiumubiquitum Fayer et al., 2010
Cryptosporidium cervine genotype
Geographic distribution. Worldwide (Li et al. 2014).
Natural hosts. Many mammal species, including ruminants, rodents, and carnivores; presumed zoonotic in humans (Li et al. 2014).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with animal feces (Li et al. 2014).
Site in human host. Duodenum and small intestine
Cryptosporidiumviatorum Elwin et al., 2012
Geographic distribution. Worldwide (Koehler et al. 2018).
Natural hosts. Rodents. Zoonotic in humans (Koehler et al. 2018).
Route of infection. Ingestion of sporulated oocysts in water, food, fomites contaminated with rodent and human feces (Koehler et al. 2018).
Site in human host. Duodenum and small intestine.
●● Ciliophora Doflein, 1901
●●● Postodesmatophora Gerassimova & Seravin, 1976
●●●● SAL (Spirotrichea-Lamellicorticata-Armophorea) Gentekaki et al., 2014
●●●●● Litostomatea Small & Lynn, 1981
●●●●●● Trichostomatia Bütschli, 1889
●●●●●●● Balantidiidae Reichenow in Doflein & Reichenow, 1929
Genus Balantioides Alexeieff, 1931
Neobalantidium Pomajbíková et al., 2013
Balantioidescoli (Malmsten, 1857)
Geographic distribution. Worldwide; high areas of endemicity include the Altiplano region of Bolivia, Philippines, New Guinea, Middle East (Schuster and Ramirez-Avila 2008).
Natural hosts. Pigs, rodents. Zoonotic in humans (Schuster and Ramirez-Avila 2008).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Schuster and Ramirez-Avila 2008).
Site in human host. Large intestine (Schuster and Ramirez-Avila 2008).
Excavates Cavalier-Smith, 2002, emend. Simpson, 2003.
● Metamonada Grassé, 1952
●● Fornicata Simpson, 2003
●●● Diplomonadida Wenyon, 1926
●●●● Hexamitidae Kent, 1880
Genus Enteromonas da Fonseca, 1915
Enteromonashominis da Fonseca, 1915
Tricercomonasintestinalis Wenyon et O’Connor, 1917
Geographic distribution. Worldwide (Ash and Orihel 2007).
Natural host. Humans (Ash and Orihel 2007).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Spriegel et al. 1989; Ash and Orihel 2007).
Site in human host. Large intestine (Ash and Orihel 2007).
Genus Giardia Künstler, 1882
Giardiaduodenalis Stiles, 1902
Cercomonasintestinalis Lambl, 1859
Giardialamblia Kofoid & Christiansen, 1915
Giardiaenterica Kofoid & Christiansen, 1920
Geographic distribution. Worldwide (Adam 2001; Cama and Mathison 2015).
Natural hosts. Two genetic assemblages implicated in human disease: A and B. Both have been found in humans and numerous non-human mammals and birds (Ryan and Caccio 2013; Heyworth 2016).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites; sexual transmission via oral-anal route (Adam 2001; Escobedo et al. 2014; Cama and Mathison 2015).
Site in human host. Duodenum, small intestine (Adam 2001; Cama and Mathison 2015).
●●● Retortamonadida Grassé, 1952
●●●● Retortamonadidae Wenrich, 1932
Genus Chilomastix Alexeieff, 1912
Chilomastixmesnili (Wenyon, 1910)
Geographic distribution. Worldwide (Ash and Orihel 2007).
Natural hosts. Humans, non-human primates (Ash and Orihel 2007).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Morimoto et al. 1996; Ash and Orihel 2007).
Site in human host. Large intestine (Ash and Orihel 2007).
Genus Retortamonas Grassi, 1879
Retortamonasintestinalis (Wenyon et O’Connoer, 1917)
Geographic distribution. Worldwide (Ash and Orihel 2007).
Natural host. Humans (Ash and Orihel 2007).
Route of infection. Ingestion of mature cysts in fecally contaminated water, food, fomites (Mendez et al. 2002; Ash and Orihel 2007).
Site in human host. Large intestine (Ash and Orihel 2007).
●● Parabasalia Honigberg, 1973
●●● Trichonomadida Kirby, 1947
●●●● Monocercomonadidae Kirby, 1944
Genus Dientamoeba Jepps & Dobell, 1918
Dientamoebafragilis Jepps & Dobell, 1918
Geographic distribution. Worldwide (Stark et al. 2016).
Natural hosts. Humans, non-human primates, pigs (Stark et al. 2016).
Route of infection. Ingestion of trophozoites in fecally contaminated water, food, fomites. A putative cyst stage has been described, but it is not yet widely accepted among protozoologists (Munasinghe et al. 2013; Stark et al. 2014, 2016).
Site in human host. Large intestine (Stark et al. 2016).
●●●● Trichomonadidae Chalmers & Pekkola, 1918, emend. Hampl et al., 2004
Genus Pentatrichomonas Mensil, 1914
Pentatrichomonashominis (Davaine, 1860)
Geographic distribution. Worldwide (Ash and Orihel 2007).
Natural hosts. Humans, non-human primates, dogs, cats, foxes, rabbits, cattle, sheep, goats, deer (Li et al. 2016, 2017, 2018).
Route of infection. Ingestion of trophozoites in fecally contaminated fomites (Ash and Orihel 2007).
Site in human host. Large intestine (Ash and Orihel 2007).
Genus Trichomonas Donné, 1837
Trichomonastenax (Müller, 1773)
Geographic distribution. Worldwide (Dubar et al. 2020).
Natural host. Humans (Dubar et al. 2020).
Route of infection. Direct person-to-person contact (Dubar et al. 2020).
Site in human host. Oral cavity; ectopic colonization of pleural cavity (Bellanger et al. 2008; Marty et al. 2017; Dubar et al. 2020).
Trichomonasvaginalis (Donné, 1836)
Geographic distribution. Worldwide (Schwebke and Burgess 2004; Kissinger 2015).
Natural host. Humans (Schwebke and Burgess 2004; Kissinger 2015).
Route of infection. Sexual contact (Schwebke and Burgess 2004; Kissinger 2015).
Site in human host. Urogenital tract; rare ectopic colonization of CSF (Schwebke and Burgess 2004; Hamilton et al. 2018).
Genus Tritrichomonas Kofoid, 1920
Tritrichomonasfoetus Reidmüller, 1928
Trichomonassuis Gruby & Delafond, 1843
Geographic distribution. Worldwide (Suzuki et al. 2016).
Natural host. Cattle, pigs, cats. Zoonotic and opportunistic in immunocompromised humans (Maritz et al. 2014; Yao and Köster 2015; Suzuki et al. 2016).
Route of infection. Unknown.
Site in human host. Respiratory tract, CNS, urogenital tract (Duboucher et al. 2006; Zalonis et al. 2011; Suzuki et al. 2016).
Genus Tetratrichomonas Parisi, 1910
Tetratrichomonas sp. cf.gallinarum
Geographic distribution. Unknown, presumed worldwide
Natural host. Unknown, presumed birds. Zoonotic in humans (Mantini et al. 2009; Maritz et al. 2014).
Route of infection. Unknown
Site in human host. Respiratory tract, possibly associated with bacterial infection (Mantini et al. 2009; Maritz et al. 2014).
Notes. This species has yet to be formally described. It was first isolated from pleural fluid in a patient with empyema. Bacterial cultures of the pleural fluid grew two Streptococcus species and Prevotella (Mantini et al. 2009). The protozoan may have been associated with bacteria and not an agent of human disease.
Tetratrichomonas sp. (undescribed species)
Tetratrichomonasempyemagena Lopez-Escamilla et al., 2013
Geographic distribution. Unknown, presumed worldwide
Natural hosts. Unknown
Route of infection. Unknown
Site in human host. Respiratory tract (Lopez-Escamilla et al. 2013)
Notes. This species was reported from two patients from Mexico(Lopez-Escamilla et al. 2013). The species was originally named T.empyemagena, but because it was not described under the criteria of the ICZN, it name should be considered nomen nudum. This isolate might be conspecific with that described by Mantini et al. (2009).
●●●● Simplicimonadidae Čepička et al., 2010
Genus Simplicimonas Čepička et al., 2010
Simplicimonassimilis Čepička et al., 2010
Geographic distribution. Undefined, possibly worldwide (Dimasuay et al. 2013).
Natural hosts. Several vertebrates; previously recorded from lizards, cattle, and chickens (Dimasuay et al. 2013).
Route of infection. Unknown.
Site in human host. Intestinal tract (Greigert et al. 2018).
Notes.Simplicimonassimilis was detected by molecular methods in four human patients in Madagascar (Greigert et al. 2018). The authors acknowledged that the parasite was not detected by microscopy and the finding may be based on spurious passage after consuming insects or another host, and further studies are required to determine if humans can serve as a reliable host (Greigert et al. 2018).
● Discoba Simpson in Hampl et al., 2009
●● Heterolobosea Page & Blanton, 1985
●●● Tetramitia Cavalier-Smith, 1993
●●●● Vahlkampfiidae Jollos, 1917
Genus Naegleria Alexeieff, 1912
Naegleriafowleri Carter, 1970
Geographic distribution. Worldwide (Gharpure et al. 2020).
Natural host. None (environmental); humans are incidental hosts (Visvesvara 2013).
Route of infection. Exposure to trophozoites and cysts in contaminated freshwater via the nasal cavity; improper use of nasal irrigation devices (Yoder et al. 2012; Visvesvara 2013).
Site in human host. CNS (Visvesvara 2013; Yoder et al. 2012; Mathison and Pritt 2018).
Genus Paravahlkampfia Brown et de Jonckheere, 1999
Paravahlkampfiafrancinae Visvesvara et al., 2009
Geographic distribution. Unknown (single case from Ohio, USA) (Visvesvara et al. 2009).
Natural host. None (environmental); humans are incidental hosts (Visvesvara et al. 2009).
Route of infection. Unknown; presumed environmental exposure.
Site in human host. CNS (Visvesvara et al. 2009).
Genus Tetramitus Perty, 1852
Tetramitusentericus (Page, 1974)
Geographic distribution. Worldwide (Brown and De Jonckheere 1999).
Natural host. None (environmental); humans are incidental hosts (Walochnik et al. 2000).
Route of infection. Presumed environmental exposure.
Site in human host. Eye (Walochnik et al. 2000).
Tetramitusjugosus (Page, 1967)
Geographic distribution. Worldwide (Enzien et al. 1989).
Natural host. None (environmental); humans are incidental hosts (Dua et al. 1998).
Route of infection. Presumed environmental exposure (Dua et al. 1998).
Site in human host. Eye (Dua et al. 1998).
Genus Vahlkampfia Chatton et Lalung-Bonnaire, 1912
Geographic distribution. Worldwide (Walochnik et al. 2000).
Natural host. None (environmental); humans are incidental hosts (Walochnik et al. 2000).
Route of infection. Unknown; presumed environmental exposure.
Site in human host. Eye (Walochnik et al. 2000).
Notes. Most reports of Vahlampfia from human clinical specimens are not characterized at the species level and may represent species currently assigned to other genera such as Tetramitus, Allovahlkampfia, and Paravahlkampfia.
●●●● Acrasidae Poche, 1913
Genus Allovahlkampfia Walochnik & Mulec, 2009
Allovahlkampfiaspelaea Walochnik & Mulec, 2009
Geographic distribution. Not fully known; described from caves in Slovenia with single human case from Egypt (Walochnik 2009; Tolba et al. 2016).
Natural host. None (environmental); humans are incidental hosts (Tolba et al. 2016).
Route of infection. Unknown; presumed environmental exposure.
Site in human host. Eye (Tolba et al. 2016).
●● Euglenozoa Cavalier-Smith, 1981, emend. Simpson, 1997
●●● Kinetoplastea Honigberg, 1963
●●●● Metakinetoplastina Vickerman in Moreira et al., 2004
●●●●● Trypanosomatida Kent 1880, emend. Vickerman in Moreira et al. 2004
●●●●●● Trypanosomatidae Doflein, 1901
Genus Crithidia Léger, 1902
Geographic distribution. Worldwide (McGhee and Cosgrove 1980).
Natural hosts. Arthropods, mainly insects. Zoonotic in humans (McGhee and Cosgrove 1980).
Route of infection. Introduction of promastigotes via the bite of infected arthropod vector (Ghobakhloo et al. 2019; Maruyama et al. 2019).
Site in human host. Skin, bone marrow (Ghobakhloo et al. 2019; Maruyama et al. 2019).
Notes.Crithidia isolates from human clinical specimens have yet to be characterized at the species level. To date, cases are known from Brazil (Maruyama et al. 2019) and Iran (Ghobakhloo et al. 2019). The vectors in the human cases are also unknown.
Genus Endotrypanum Mesnil & Brimont, 1908
Endotrypanumcolombiensis (Kreuter et al., 1991)
Geographic distribution. Colombia (Kreutzer et al. 1991).
Natural hosts. Mammalian hosts are sloths; zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Kreutzer et al. 1991).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Kreutzer et al. 1991).
Site in human host. Skin (Kreutzer et al. 1991)
Endotrypanumequatoriensis (Grimaldi-Junior et al., 1992)
Geographic distribution. Colombia, Ecuador (Grimaldi Junior et al. 1992).
Natural hosts. Mammalian hosts are sloths and squirrels; zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Grimaldi Junior et al. 1992).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Grimaldi Junior et al. 1992).
Site in human host. Skin (Grimaldi Junior et al. 1992).
Genus Leishmania Ross, 1903
Euleishmania Cupolillo et al., 2000
SubgenusLeishmania Ross, 1903
Leishmaniai (L .) aethiopicaBray et al., 1973
Geographic distribution. Africa (Ethiopia, Kenya, Uganda), Yemen (van Henten et al. 2018).
Natural hosts. Mammalian hosts include humans, rock hyraxes, and other wild mammals. Arthropod vectors are sand flies in the genus Phlebotomus, mainly P.longipes and P.pedifer (Bray et al. 1973).
Route of infection. Introduction of promastigotes via the bite of infected Phlebotomus sand fly (van Henten et al. 2018).
Site in human host. Skin (van Henten et al. 2018).
Leishmania (L.) amazonensis Lainson & Shaw, 1972
Leishmaniagarnhami Scorza et al., 1978
Geographic distribution. Amazonian South America (Brazil, Venezuela, Bolivia) (Torres-Guerrero et al. 2017).
Natural hosts. Mammals and birds, including humans, rodents, dogs, chickens. Arthropod vectors are sand flies in the genus Lutzomyia (Torres-Guerrero et al. 2017; Valdivia et al. 2017).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Torres-Guerrero et al. 2017; Valdivia et al. 2017).
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Torres-Guerrero et al. 2017).
Leishmania (L.) donovani (Laveran & Mesnil, 1903)
Leishmaniaarchibaldi Castellani & Chalmers, 1919
Geographic distribution. Indian subcontinent, China, Central Africa; hot spots of endemicity include India, Bangladesh, Nepal, Sudan (Lukes et al. 2007; Ready 2014).
Natural hosts. Mammalian hosts include humans, dogs, foxes, marsupials, and rodents. Arthropod vectors are sand flies in the genera Phlebotomus (Old World) and Lutzomyia (New World) (Lukes et al. 2007; Ready 2014).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (Torres-Guerrero et al. 2017).
Site in human host. Skin, spleen, liver, small intestine, lymph nodes (Torres-Guerrero et al. 2017).
Leishmania (L.) infantum Nicolle, 1908
Leishmaniachagasi da Cunha & Chagas, 1937
Geographic distribution. Mediterranean Europe and Africa, southeastern Europe, Middle East, Central Asia, Central and South America (Mexico, Venezuela, Brazil, Bolivia) (Pratlong et al. 2013; Steverding 2017).
Natural hosts. Mammalian hosts include dogs, cats, foxes, lagomorphs, rodents, marsupials, and others; zoonotic in humans. Arthropod vectors are sand flies in the genera Phlebotomus (Old World) and Lutzomyia (New World) (Millan et al. 2014).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (Torres-Guerrero et al. 2017).
Site in human host. Skin, spleen, liver, small intestine, lymph nodes (Torres-Guerrero et al. 2017).
Leishmania (L.) major Yakimoff & Schokhor, 1914
Geographic distribution. Northern and Central Africa, Middle East, India, China (Guerrant et al. 2006; Steverding 2017).
Natural hosts. Humans; gerbils and birds may serve as reservoir hosts; dogs can become infected but are not adequate reservoir hosts for human disease. Arthropod vectors are sand flies in the genus Phlebotomus (Al-Bajalan et al. 2018).
Route of infection. Introduction of promastigotes via the bite of infected Phlebotomus sand fly (Torres-Guerrero et al. 2017).
Site in human host. Skin (Torres-Guerrero et al. 2017).
Leishmania (L.) mexicana Biagi, 1953, emend. Garnham, 1962
Leishmaniapifanoi Medina & Romero, 1962
Geographic distribution. Texas, Mexico, Belize, Guatemala, Brazil, Ecuador, Peru, Venezuela (Steverding 2017).
Natural hosts. Mammalian hosts include humans, dogs, rodents, and bats. Arthropod vectors are sand flies in the genus Lutzomyia (Berzunza-Cruz et al. 2015).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (L.) tropica Wright, 1903
Geographic distribution. North and Central Africa, Middle East, Central Asia, India (Steverding 2017).
Natural hosts. Mammalian hosts include humans, rock hyraxes, gundi, and dogs (although dogs are not an adequate reservoir host for human disease). Arthropod vectors are sand flies in the genus Phlebotomus (Ajaoud et al. 2013).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (L.) venezuelensis (Bonfante-Garrido, 1980)
Geographic distribution. Venezuela, northern South America (Steverding 2017).
Natural hosts. Mammalian hosts include humans, cats. Arthropod vectors are sand flies in the genus Lutzomyia (Rivas et al. 2018).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (L .) waltoniShaw et al., 2015
Geographic distribution. Dominican Republic (Shaw et al. 2015).
Natural hosts. Mammalian hosts unknown, rats may serve as reservoir hosts; presumed zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Shaw et al. 2015).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Shaw et al. 2015).
Site in human host. Skin (Shaw et al. 2015).
SubgenusMundinia Shaw et al. in Espinosa et al., 2016
Leishmania (M.) martiniquensisDesbois et al., 2014
Geographic distribution. Martinique, Thailand (Desbois et al. 2014; Pothirat et al. 2014).
Natural hosts. Mammalian hosts are humans. Rats may serve as reservoir hosts. Arthropod vectors are sand flies, possibly in the genera Sergentomyia (Old World) and Lutzomyia (New World) (Leelayoova et al. 2017).
Route of infection. Introduction of promastigotes via the bite of infected sand fly
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Desbois et al. 2014; Liautaud et al. 2015).
Leishmania (M.) orientalis Jariyapan et al., 2018
Leishmaniasiamensis Sukmee et al., 2008
Geographic distribution. Thailand (Sukmee et al. 2008; Jariyapan et al. 2018).
Natural hosts. Mammalian hosts are humans. Arthropod vectors are sand flies. (Sukmee et al. 2008; Jariyapan et al. 2018).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (genus unknown).
Site in human host. Skin (Sukmee et al. 2008; Jariyapan et al. 2018).
SubgenusSauroleishmania Ranque, 1973
Leishmania (S.) tarentolae Weynon, 1921
Geographic distribution. North Africa, southern Europe, Middle East (Klatt et al. 2019).
Natural hosts. Definitive hosts are lizards. Arthropod vectors are sand flies in the genus Sergentomyia. Zoonotic in humans (Klatt et al. 2019).
Route of infection. Introduction of promastigotes in bite of infected Sergentomyia sand fly (Klatt et al. 2019; Pombi et al. 2020).
Site in human host. Blood (Pombi et al. 2020).
Notes. The single human case was diagnosed by molecular detection (only) in blood (Pombi et al. 2020).
SubgenusViannia Lainson & Shaw, 1987
Leishmania (V.) braziliensis Vianna, 1911
Geographic distribution. Amazonian South America (Brazil, Bolivia, Venezuela, Peru), Guatemala (Castro et al. 2007; Steverding 2017).
Natural hosts. Mammalian hosts include humans, dogs, rodents, and marsupials. Arthropod vectors are sand flies in the genus Lutzomyia (Castro et al. 2007).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) guyanensis Floch, 1954
Geographic distribution. Northern South America (French Guiana, Suriname, Brazil, Bolivia) (Guerra et al. 2011; Steverding 2017).
Natural hosts. Mammalian hosts include sloths, anteaters, rodents, marsupials, and humans. Arthropod vectors are sand flies in the genus Lutzomyia (Guerra et al. 2011).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) lainsoni Silveira et al., 1987
Geographic distribution. Brazil, Bolivia, Ecuador, Peru, Suriname, French Guiana (Kato et al. 2016; Mans et al. 2017; Steverding 2017).
Natural hosts. Mammalian host is lowland paca; zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Mans et al. 2017).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V .) lindenbergi Silveira et al., 2002
Geographic distribution. Brazil (Cantanhêde et al. 2019).
Natural hosts. Mammalian hosts unknown; presumed zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Cantanhêde et al. 2019).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) naiffi Lainson & Shaw, 1989
Geographic distribution. Brazil, Bolivia, Peru (Lainson and Shaw 1989; Fagundes-Silva et al. 2015).
Natural hosts. Mammalian hosts are armadillos; zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Lainson and Shaw 1989; Fagundes-Silva et al. 2015).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) panamensis Lainson & Shaw, 1972
Geographic distribution. Central and South America (Steverding 2017; Torres-Guerrero et al. 2017).
Natural hosts. Mammalian hosts include sloths, procyonids, rodents, humans, and non-human primates. Arthropod vectors are sand flies in the genus Lutzomyia (Steverding 2017; Torres-Guerrero et al. 2017).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) peruviana Velez, 1913
Geographic distribution. Peru, Bolivia (Steverding 2017; Torres-Guerrero et al. 2017).
Natural hosts. Mammalian hosts include humans, rodents, marsupials, and domestic dogs. Arthropod vectors are sand flies in the genera Lutzomyia and possibly Pintomyia (Kato et al. 2021).
Route of infection. Introduction of promastigotes via the bite of infected sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin, mucosal membranes of nose, throat, and mouth (Steverding 2017; Torres-Guerrero et al. 2017).
Leishmania (V.) shawi Lainson et al., 1989
Geographic distribution. Brazil (Lainson et al. 1989)
Natural hosts. Mammalian hosts include non-human primates, sloths, coati; zoonotic in humans. Arthropod vectors are sand flies in the genus Lutzomyia (Lainson et al. 1989).
Route of infection. Introduction of promastigotes via the bite of infected Lutzomyia sand fly (Steverding 2017; Torres-Guerrero et al. 2017).
Site in human host. Skin (Steverding 2017; Torres-Guerrero et al. 2017).
Genus Leptomonas Kent, 1880
Leptomonasseymouri (Wallace, 1877)
Geographic distribution. Worldwide (Kraeva et al. 2015).
Natural hosts. Insects. Zoonotic in humans (Ghosh et al. 2012; Kraeva et al. 2015; Thakur et al. 2020).
Route of infection. Presumed introduction of promastigotes via the bite of infected Phlebotomus sand flies (Ghosh et al. 2012; Kraeva et al. 2015; Thakur et al. 2020).
Site in human host. Skin, spleen, bone marrow (Ghosh et al. 2012; Kraeva et al. 2015; Thakur et al. 2020)
Notes. Human cases of L.seymouri to date have been found in Southeast Asia associated with co-infection with Leishmaniadonovani, suggesting incidental human infection after the bite of an infected sand fly vector.
Genus Trypanosoma Gruby, 1843
SubgenusHerpetosoma Doflein, 1901
Trypanosoma (H.) lewisi Laveran & Mesnil, 1901
Geographic distribution. Cosmopolitan (Desquesnes et al. 2002).
Natural hosts. Mammalian hosts are rats (Rattus spp.); zoonotic in humans. Arthropod vectors are rat fleas Nosophyllusfasciatus and Xenopsyllacheopis (Desquesnes et al. 2002).
Route of infection. Ingestion of infected fleas or their feces (Desquesnes et al. 2002).
Site in human host. Blood (Verma et al. 2011; de Sousa 2014).
Trypanosoma (H.) rangeli Tejera, 1920
Trypanosomasaimirii Rodhain, 1941
Geographic distribution. South America (Guhl and Vallejo 2003).
Natural hosts. Mammalian hosts include coati, sloths, tamandua, and opossums; zoonotic in humans. Arthropod vectors are triatomine bugs, most-notably members of the genus Rhodnius (Miles et al. 1983; Guhl and Vallejo 2003; Ferreira L de et al. 2015).
Route of infection. Introduction of trypomastigotes via the bite of infected triatomine bug (Guhl and Vallejo 2003; Ferreira L de et al. 2015).
Site in human host. Blood (Guhl and Vallejo 2003; Ferreira L de et al. 2015).
SubgenusSchizotrypanum Chagas, 1909
Trypanosoma (S.) cruzi Chagas, 1909
Geographic distribution. Southern United States, Central and South America (Bern et al. 2011; Kirchhoff 2011; Conners et al. 2016).
Natural hosts. Mammalian hosts include humans and many domestic and wild mammals. Arthropod vectors are triatomine bugs, most-notably members of the genera Triatoma, Panstrongylus, and Rhodnius (Kirchhoff 2011).
Route of infection. Introduction of metacyclic trypomastigotes in the feces of infected triatomine bug when rubbed into wounds or mucus membranes; ingestion of food contaminated with bugs or their feces; transplacentally from mother to fetus; via blood transfusion and organ transplantation (Coura 2015; Conners et al. 2016; Lidani et al. 2019).
Site in human host. Blood (acute infection, reactivation); heart muscle, esophagus, large intestine, peripheral nervous system, CNS, other organs (chronic infection) (Coura 2015; Conners et al. 2016; Lidani et al. 2019).
SubgenusTrypanozoon Lühe, 1906
Trypanosoma (T.) brucei gambiense (Dutton, 1902)
Geographic distribution. West-central Africa; hot spots of endemicity include Angola, Democratic Republic of Congo, South Sudan, Central African Republic, Uganda (Brun et al. 2010; Franco et al. 2014).
Natural hosts. Mammalian hosts include humans, non-human primates, and ungulates. Arthropod vectors are tsetse flies in the genus Glossina (Brun et al. 2010; Franco et al. 2014).
Route of infection. Introduction of trypomastigotes via the bite of infected Glossina tsetse fly (Brun et al. 2010).
Site in human host. Blood, lymphatics, CNS (Brun et al. 2010).
Trypanosoma (T.) brucei rhodesiense (Stephen & Fantham, 1910)
Geographic distribution. East and southeast Africa; hot spots of endemicity include Malawi, Zambia, Tanzania, Botswana, Kenya (Brun et al. 2010; Franco et al. 2014).
Natural hosts. Mammalian hosts include livestock and wild ungulates; zoonotic in humans. Arthropod vectors are tsetse flies in the genus Glossina (Brun et al. 2010; Franco et al. 2014).
Route of infection. Introduction of trypomastigotes via the bite of infected Glossina tsetse fly (Brun et al. 2010).
Site in human host. Blood, lymphatics, CNS (Brun et al. 2010).
Trypanosoma (T.) evansi Balbiani, 1888
Geographic distribution. Equatorial regions of Africa, Asia, Latin America (Van Vinh Chau et al. 2016).
Natural hosts. Mammalian hosts include horses, camels, bovids; zoonotic in humans. Arthropod vectors are biting flies in the genera Stomoxys and Tabanus (Van Vinh Chau et al. 2016).
Route of infection. Introduction of trypomastigotes via the bite of infected flies; possibly direct contact with blood/wounds of infected animals (Joshi et al. 2005; Powar et al. 2006; Van Vinh Chau et al. 2016).
Site in human host. Blood (Joshi et al. 2005; Powar et al. 2006; Van Vinh Chau et al. 2016).
Opisthokonta Cavalier-Smith, 1987, emend. Adl et al., 2005
● Holozoa Lang et al., 2002
●● Metazoa Haeckel, 1874, emend. Adl et al. 2005
●●● Protostomia Grobben, 1908
●●●● Spiralia Edgecombe et al., 2011
●●●●● Acanthocephala Koelreuther, 1771
●●●●●● Oligacanthorhynchida Petrotschenko, 1956
●●●●●●● Oligacanthorhynchidae Southwell & Macfie, 1925
Genus Macracanthorhynchus Travassos, 1917
Macracanthorhynchushirudinaceus (Pallas, 1781)
Taeniahaeruca Pallas, 1776
Echinorhynchusgigas Bloch, 1782
Geographic distribution. Worldwide (Mathison et al. 2016).
Natural hosts. Intermediate hosts are insects, primarily scarabaeoid beetles. Definitive hosts are pigs; dogs and other mammals can serve as reservoir hosts. Zoonotic in humans (Mathison et al. 2016).
Route of infection. Ingestion of cystacanths in infected insect intermediate host (Mathison et al. 2016).
Site in human host. Small intestine (Mathison et al. 2016).
Macracanthorhynchusingens (von Linstow, 1879)
Geographic distribution. Eastern North America (Elkins and Nickol 1983; Richardson et al. 2017).
Natural hosts. Intermediate hosts are millipedes. Definitive hosts are raccoons (Procyonlotor) and American black bear (Ursusamericanus); many other mammals, especially carnivores, can serve as definitive hosts. Snakes and other animals may serve as paratenic hosts. Zoonotic in humans (Elkins and Nickol 1983; Richardson et al. 2017).
Route of infection. Ingestion of cystacanths in infected arthropod intermediate host or paratenic hosts (Mathison et al. 2016; Chancey et al. 2021).
Site in human host. Small intestine (Mathison et al. 2016; Chancey et al. 2021).
●●●●●● Moniliformida Schmidt, 1972
●●●●●●● Moniliformidae Van Cleave, 1924
Genus Moniliformis Travassos, 1915
Moniliformismoniliformis (Bremser, 1811)
Echinorhynchusgrassi Railliet, 1893
Echinorhynchuscanis Porta, 1914
Echinorhynchusbelgicus Railliet, 1918
Moniliformismoniliformissiciliensis Meyer, 1932
Moniliformismoniliformisagypticus Meyer, 1932
Moniliformisdubius Meyer, 1932
Geographic distribution. Worldwide (Mathison et al. 2016).
Natural hosts. Intermediate hosts are insects, primarily beetles and cockroaches. Definitive hosts are primarily rodents and carnivores. Zoonotic in humans (Mathison et al. 2016).
Route of infection. Ingestion of cystacanths in infected insect intermediate host (Mathison et al. 2016).
Site in human host. Small intestine (Mathison et al. 2016).
●●●●●● Echinorhynchida Petrotschenko, 1956
●●●●●●● Echinorhynchidae Cobbold, 1876
Genus Acanthocephalus Koelreuther, 1771
Acanthocephalusrauschi (Schmidt, 1969)
Geographic distribution. Alaska (Schmidt 1969).
Natural hosts. Alaskan grayling (Thymallusarcticus). Otters can serve as paratenic hosts. Zoonotic in humans (Schmidt 1969).
Route of infection. Unknown; presumed ingestion of cystacanths in infected intermediate host.
Site in human host. Peritoneum (Schmidt 1969, 1971).
Genus Pseudoacanthocephalus Petrotschenko, 1958
Pseudoacanthocephalusbufonis (Shipley, 1903)
Acanthocephalussinensis Van Cleave, 1937
Geographic distribution. Southeast Asia, Hawaii (Barton and Pichelin 1999; Bush et al. 2009).
Natural hosts. Toads. Zoonotic in humans (Bush et al. 2009).
Route of infection. Unknown; presumed ingestion of cystacanths in infected intermediate host.
Site in human host. Small intestine (Schmidt 1971).
●●●●●● Polymorphida Petrotschenko, 1956
●●●●●●● Polymorphidae Meyer, 1931
Genus Bolbosoma Porta, 1908
Bolbosomanipponicum Yamaguti, 1939
Geographic distribution. North Atlantic (Yamaguti 1963).
Natural hosts. Marine crustaceans serve as intermediate hosts. Fish and cephalopods may serve as paratenic hosts. Whales and seals serve as definitive hosts. Zoonotic in humans (Yamaguti 1963).
Route of infection. Unknown; presumed ingestion of cystacanths in infected fish paratenic hosts.
Site in human host. Small intestine (Yamamoto et al. 2018).
Bolbosoma sp. cf. capitatum (von Linstow, 1880)
Geographic distribution. Worldwide (Amin and Margolis 1998).
Natural hosts. Marine crustaceans serve as intermediate hosts. Whales serve as definitive hosts. Zoonotic in humans (Amin and Margolis 1998).
Route of infection. Unknown; presumed ingestion of cystacanths in infected fish paratenic hosts.
Site in human host. Small intestine (Arizono et al. 2012).
Notes. The single case was reported from Japan as Bolbosomacf.capitatim based on molecular and histological examination (Arizono et al. 2012).
Genus Corynosoma Lühe, 1904
Corynosomastrumosum (Rudolphi, 1802)
Geographic distribution. Worldwide (Aznar et al. 2006; Leidenberger et al. 2020).
Natural hosts. Intermediate hosts are marine amphipods. Several groups of fish may serve as paratenic hosts. Definitive hosts are seals, walrus, beluga whale. Zoonotic in humans (Aznar et al. 2006; Leidenberger et al. 2020; Nickol et al. 2002).
Route of infection. Ingestion of cystacanths in infected fish paratenic host (Schmidt 1971).
Site in human host. Small intestine (Schmidt 1971).
Corynosomavillosum Van Cleave, 1953
Geographic distribution. North Pacific (Moles 1982).
Natural hosts. Intermediate hosts are marine amphipods. Several groups of fish may serve as paratenic hosts. Definitive hosts are pinnipeds and whales. Zoonotic in humans (Moles 1982).
Route of infection. Ingestion of cystacanths in infected fish paratenic host (Fujita et al. 2016).
Site in human host. Small intestine (Fujita et al. 2016).
Corynosoma sp. cf. validum Van Cleave, 1953
Geographic distribution. North Pacific (Ionita et al. 2008).
Natural hosts. Intermediate hosts are marine amphipods. Several groups of fish may serve as paratenic hosts. Definitive host is the northern fur seal (Callorhinusursinus), and other pinnipeds. Zoonotic in humans (Ionita et al. 2008).
Route of infection. Ingestion of cystacanths in infected fish paratenic host (Takahashi et al. 2016).
Site in human host. Small intestine (Takahashi et al. 2016).
Notes. The single case was reported from Japan as Corynosomacf.validum based on DNA sequencing (Takahashi et al. 2016).
●●●●● Annelida Lamarck, 1802
●●●●●● Hirudinea Lamarck, 1818
●●●●●●● Rhynchobdellida Blanchard, 1894
●●●●●●●● Glossiphoniidae Vaillant, 1890
Genus Haementeria de Filippi, 1849
Haementeriaacuecueyetzin Oceguera-Figueroa, 2008
Geographic distribution. Mexico (Oceguera-Figueroa 2008).
Natural hosts. Various vertebrates. Zoonotic on humans (Oceguera-Figueroa 2008; Charruau et al. 2020).
Route of infection. Exposure to fresh water (Oceguera-Figueroa 2008; Charruau et al. 2020).
Site in human host. Skin (Oceguera-Figueroa 2008).
Vectored pathogens. None.
Haementeriaghilianii de Filippi, 1849
Geographic distribution. Amazon South America (Sawyer et al. 1981).
Natural hosts. Various mammals. Zoonotic on humans (Sawyer et al. 1981; Farrar 2014).
Route of infection. Exposure to fresh water (Farrar 2014).
Site in human host. Skin (Farrar 2014).
Vectored pathogens. None.
Genus Parabdella Autrum, 1936
Parabdellaquadrioculata (Moore, 1930)
Geographic distribution. East Asia (Moore 1930).
Natural hosts. Freshwater turtles and frogs. Zoonotic on humans (Moore 1930).
Route of infection. Exposure to fresh water (Yamauchi et al. 2013).
Site in human host. Skin (Yamauchi et al. 2013).
Vectored pathogens. None.
Genus Placobdella Blanchard, 1893
Placobdellacostata (Müller, 1846)
Placobdellacatenigera Moquin-Tandon, 1846
Geographic distribution. Mediterranean Region, Central Europe (Wilkialis 1973).
Natural hosts. Freshwater turtles. Zoonotic on humans (Wilkialis 1973).
Route of infection. Exposure to fresh water (Aloto 2018).
Site in human host. Skin (Aloto 2018).
Vectored pathogens. None.
●●●●●●● Hirudiniformes Caballero, 1952
●●●●●●●● Xerobdellidae Moore, 1946
Genus Diestecostoma Vaillant, 1890
Heterobdella Baird, 1869
Hygrobdella Caballero, 1940
Diestecostomamexicana (Baird, 1869)
Geographic distribution. Central America (Oceguera-Figueroa and León-Règagnon 2014).
Natural hosts. Various mammals. Zoonotic on humans (Farrar 2014).
Route of infection. Environmental exposure (Farrar 2014).
Site in human host. Skin (Farrar 2014).
Vectored pathogens. None.
●●●●●●●● Haemadipsidae Blanchard, 1896
Genus Haemadipsa Tennent, 1859
Haemadipsahainana Song, 1977
Geographic distribution. Southeast Asia (Tessler et al. 2018).
Natural hosts. Various mammals and birds. Zoonotic on humans (Tessler et al. 2018).
Route of infection. Environmental exposure (Tessler et al. 2018).
Site in human host. Skin (Tessler et al. 2018).
Vectored pathogens. None.
Haemadipsainterrupta Moore, 1935
Geographic distribution. Southeast Asia (Tessler et al. 2018).
Natural hosts. Various mammals and birds. Zoonotic on humans (Tessler et al. 2018).
Route of infection. Environmental exposure (Tessler et al. 2018).
Site in human host. Skin (Tessler et al. 2018).
Vectored pathogens. None.
Haemadipsajaponica Whitman, 1886
Geographic distribution. East Asia (Aizawa and Morishima 2018).
Natural hosts. Various mammals, birds, amphibians. Zoonotic on humans (Hanya et al. 2019).
Route of infection. Environmental exposure (Ji-Tuan 1997).
Site in human host. Skin, mucous membranes or the rectum and genital tract (Ji-Tuan 1997).
Vectored pathogens. None.
Haemadipsapicta Moore, 1929
Geographic distribution. Southeast Asia (Lai et al. 2011).
Natural hosts. Various large mammals, including humans (Lai et al. 2011).
Route of infection. Environmental exposure (Fogden and Proctor 1985; Lai et al. 2011).
Site in human host. Skin (Fogden and Proctor 1985; Lai et al. 2011).
Vectored pathogens. None.
Haemadipsarjukjuana Oka, 1910
Geographic distribution. East Asia (Lai et al. 2011; Won et al. 2014).
Natural hosts. Various mammals, including humans, and birds (Lai et al. 2011).
Route of infection. Environmental exposure (Lai et al. 2011; Won et al. 2014).
Site in human host. Skin (Lai et al. 2011; Won et al. 2014).
Vectored pathogens. None
Haemadipsasylvestris Blanchard, 1894
Geographic distribution. Southeast Asia (Farrar 2014).
Natural hosts. Various mammals. Zoonotic on humans (Farrar 2014).
Route of infection. Environmental exposure (Farrar 2014).
Site in human host. Skin (Farrar 2014).
Vectored pathogens. None.
Haemadipsatrimaculosa Ngamprasertwong et al., 2007
Geographic distribution. Southeast Asia (Ngamprasertwong et al. 2007; Tessler et al. 2018).
Natural hosts. Various mammals and birds. Zoonotic on humans (Ngamprasertwong et al. 2007).
Route of infection. Environmental exposure (Tessler et al. 2018).
Site in human host. Skin (Tessler et al. 2018).
Vectored pathogens. None
Haemadipsazeylanica (Moquin-Tandon, 1826)
Geographic distribution. Japan, Southeast Asia (Fogden and Proctor 1985).
Natural hosts. Various amphibians and mammals. Zoonotic on humans (Fogden and Proctor 1985).
Route of infection. Environmental exposure (Fogden and Proctor 1985).
Site in human host. Skin (Fogden and Proctor 1985).
Vectored pathogens. None.
Genus Phytobdella Blanchard, 1894
Phytobdellacatenifera Moore, 1942
Geographic distribution. Malaysia (Farrar 2014).
Natural hosts. Reptiles. Zoonotic on humans (Farrar 2014).
Route of infection. Environmental exposure (Farrar 2014).
Site in human host. Skin (Farrar 2014).
Vectored pathogens. None.
●●●●●●●● Hirudinidae Whitman, 1886
Genus Hirudo Linnaeus, 1758
Hirudomedicinalis Linnaeus, 1758
Geographic distribution. Europe, Asia (Kutschera and Elliott 2014).
Natural hosts. Immature stages usually on amphibians. Adults on mammals. Zoonotic on humans (Kutschera and Elliott 2014).
Route of infection. Exposure to fresh water (Kutschera and Elliott 2014).
Site in human host. Skin (Kutschera and Elliott 2014).
Vectored pathogens.Aeromonas spp. (Graf 1999).
Hirudonipponia Whitman, 1886
Geographic distribution. Russia, Japan, Southeast Asia (Yang 1996).
Natural hosts. Immature stages usually on amphibians. Adults on mammals. Zoonotic on humans (Yang 1996).
Route of infection. Exposure to fresh water (Oda et al. 1984).
Site in human host. Skin, Eye (Oda et al. 1984).
Vectored pathogens. None.
Hirudoorientalis Utevsky & Trontelj, 2005
Geographic distribution. Central Asia, Eastern Europe (Utevsky and Trontelj 2005).
Natural hosts. Immature stages usually on amphibians. Adults on mammals. Zoonotic on humans (Utevsky and Trontelj 2005).
Route of infection. Exposure to fresh water (Utevsky and Trontelj 2005).
Site in human host. Skin, Eye (Utevsky and Trontelj 2005).
Vectored pathogens.Aeromonas spp. (Laufer et al. 2008).
Hirudotroctina Johnson, 1816
Geographic distribution. North Africa, Iberian Peninsula (Marrone and Canale 2019).
Natural hosts. Immature stages usually on amphibians. Adults on mammals. Zoonotic on humans (Trontelj and Utevsky 2005).
Route of infection. Exposure to fresh water (Trontelj and Utevsky 2005).
Site in human host. Skin, Eye (Trontelj and Utevsky 2005).
Vectored pathogens. None.
Hirudoverbena Carena, 1820
Geographic distribution. Mediterranean Europe (Marrone and Canale 2019).
Natural hosts. Immature stages usually on amphibians. Adults on mammals. Zoonotic on humans (Kutschera and Elliott 2014).
Route of infection. Exposure to fresh water (Kutschera and Elliott 2014).
Site in human host. Skin (Kutschera and Elliott 2014).
Vectored pathogens.Aeromonas spp. (Laufer et al. 2008).
Genus Hirudinaria Whitman, 1886
Hirudinariamanillensis (Lesson, 1842)
Hirudomultistriata Schmarda, 1861
Hirudoluzoniae Kinberg, 1866
Hirudomaculosa Grube, 1868
Hirudomaculata Baird, 1869
Limnatisgranulosa Blanchard, 1893
Hirudoboyntoni Wharton, 1913
Geographic distribution. Southeast Asia (Jeratthitikul et al. 2020).
Natural hosts. Mammals, including buffalo, cattle. Zoonotic in humans (Jeratthitikul et al. 2020).
Route of infection. Exposure to fresh water (Hii et al. 1978).
Site in human host. Upper respiratory tract (Hii et al. 1978).
Vectored pathogens. None
Genus Limnatis Moquin-Tandon, 1827
Limnatisnilotica (Savigny, 1822)
Geographic distribution. Southern Europe, North Africa, Middle East (Arfuso et al. 2019).
Natural hosts. Mammals, including sheep, cattle, dogs, and donkeys. Zoonotic on humans (Arfuso et al. 2019).
Route of infection. Exposure to fresh water
Site in human host. Upper respiratory tract (Almallah 1968; Ağin et al. 2008).
Vectored pathogens. None.
Genus Poecilobdella Blanchard, 1893
Poecilobdellagranulosa (Savigny, 1822)
Geographic distribution. India, Sri Lanka, Southeast Asia (Nesemann and Sharma 2001).
Natural hosts. Amphibians, Mammals. Zoonotic in humans (Nesemann and Sharma 2001).
Route of infection. Exposure to fresh water (Zainuddin et al. 2016).
Site in human host. Skin, upper respiratory tract (Zainuddin et al. 2016).
Vectored pathogens. None.
Poecilobdellaviridis Moore in Harding & Moore, 1927
Geographic distribution. India, Sri Lanka (Kulkarni et al. 1977).
Natural hosts. Amphibians, Mammals. Zoonotic in humans (Kulkarni et al. 1977).
Route of infection. Exposure to fresh water (Zainuddin et al. 2016).
Site in human host. Upper respiratory tract (Zainuddin et al. 2016).
Vectored pathogens. None.
●●●●●●●● Macrobdellidae Richardson, 1969
Genus Macrobdella Verrill, 1872
Macrobdelladecora (Say, 1824)
Geographic distribution. Eastern North America, Mexico (Phillips et al. 2016, 2019).
Natural hosts. Various vertebrate animals. Zoonotic on humans (Phillips et al. 2016, 2019).
Route of infection. Exposure to fresh water (Phillips et al. 2016, 2019).
Site in human host. Skin (Phillips et al. 2016, 2019).
Vectored pathogens. None.
Macrobdelladiplotertia Meyer, 1975
Geographic distribution. East-central United States (Phillips et al. 2016, 2019).
Natural hosts. Various vertebrate animals. Zoonotic on humans (Phillips et al. 2016, 2019).
Route of infection. Exposure to fresh water (Phillips et al. 2016, 2019).
Site in human host. Skin (Phillips et al. 2016, 2019).
Vectored pathogens. None.
Macrobdelladitetra Moore, 1953
Geographic distribution. Southeastern United States (Phillips et al. 2016, 2019).
Natural hosts. Various vertebrate animals. Zoonotic on humans(Phillips et al. 2016, 2019).
Route of infection. Exposure to fresh water (Phillips et al. 2016, 2019).
Site in human host. Skin (Phillips et al. 2016, 2019).
Vectored pathogens. None.
Macrobdellamimicus Phillips, 2019
Geographic distribution. Northeastern United States (Phillips et al. 2019).
Natural hosts. Various vertebrate animals. Zoonotic on humans (Phillips et al. 2019).
Route of infection. Exposure to fresh water (Phillips et al. 2019).
Site in human host. Skin (Phillips et al. 2019).
Vectored pathogens. None.
Macrobdellasestertia Whitman, 1886
Geographic distribution. Northeastern United States (Phillips et al. 2016, 2019).
Natural hosts. Various vertebrate animals. Zoonotic on humans (Phillips et al. 2016, 2019).
Route of infection. Exposure to fresh water (Phillips et al. 2016, 2019).
Site in human host. Skin (Phillips et al. 2016, 2019).
Vectored pathogens. None.
●●●●●●●● Praeobdellidae Sawyer, 1986
Genus Dinobdella Moore in Harding & Moore, 1927
Dinobdellaferox (Blanchard, 1896)
Geographic distribution. India, Southeast Asia (Lai 2019).
Natural hosts. Various mammals. Zoonotic on humans (Lai 2019).
Route of infection. Exposure to fresh water (Makiya et al. 1988).
Site in human host. Nasal mucosa (Makiya et al. 1988).
Vectored pathogens. None.
Genus Myxobdella Oka, 1917
Myxobdellaafricana Moore, 1939
Geographic distribution. Sub-Saharan Africa (Cundall et al. 1986; Estambale et al. 1992).
Natural hosts. Mammals, including dogs. Zoonotic in humans (Cundall et al. 1986; Estambale et al. 1992).
Route of infection. Exposure to fresh water (Cundall et al. 1986; Estambale et al. 1992).
Site in human host. Upper respiratory tract (Cundall et al. 1986; Estambale et al. 1992).
Vectored pathogens. None.
Genus Tyrannobdella Philipps et al., 2010
Tyrannobdellarex Phillips et al., 2010
Geographic distribution. Amazon South America (Phillips et al. 2010).
Natural hosts. Unknown; presumed zoonotic on humans (Phillips et al. 2010).
Route of infection. Exposure to fresh water (Phillips et al. 2010).
Site in human host. Nasopharynx (Phillips et al. 2010).
Vectored pathogens. None.
●●●●● Cestoda Rudolphi, 1809
●●●●●● Eucestoda Southwell, 1930
●●●●●●● DiphyllobothriideaKuchta et al., 2008
●●●●●●●● Diphyllobothriidae Lühe, 1910
Genus Adenocephalus Nybelin, 1931
Adenocephaluspacificus Nybelin, 1931
Adenocephalusseptentrionalis Nybelin, 1931
Diphyllobothriumarctocephali Drummond, 1937
Diphyllobothriumkrotovi Delyamure, 1955
Dibothriocephalusatlanticum Delyamure & Parukhin, 1968
Geographic distribution. Coastal Pacific waters and southern Africa (Hernandez-Orts et al. 2015; Kuchta et al. 2015).
Natural hosts. The first arthropod intermediate host is unknown, but presumed to be marine copepods. The second intermediate hosts are various marine fish. Definitive hosts are eared seals and sea lions; dogs and jackals can serve as reservoir hosts. Zoonotic in humans (Hernandez-Orts et al. 2015; Kuchta et al. 2015).
Route of infection. Ingestion of plerocercoids in infected fish (Kuchta et al. 2015).
Site in human host. Small intestine (Kuchta et al. 2015).
Genus Dibothriocephalus Lühe, 1899
Dibothriocephalusdalliae (Rausch, 1956)
Geographic distribution. Northern Pacific (Alaska and northeastern Siberia) (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish, primarily Alaska blackfish (Dalliapectoralis). Definitive hosts are Arctic fox, with domestic dogs as reservoir hosts. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Dibothriocephalusdendriticus (Nitzsch, 1824)
Dibothriocephalusfissiceps Creplin, 1829
Dibothriocephaluscordiceps Leidy, 1872
Dibothriocephalusexile Linton, 1892
Sparganumsebago Ward, 1910
Dibothriocephalusminor Cholodkovsky, 1916
Diphyllobothriumcanadense Cooper, 1921
Diphyllobothriumstrictum Talysin, 1932
Diphyllobothriumobdoriense Piotnikoff, 1933
Diphyllobothriumlaruei Vergeer, 1934
Diphyllobothriumnenzi Petrov, 1938
Diphyllobothriumoblongatum Thomas, 1946
Diphyllobothriummedium Fahmy, 1954
Diphyllobothriummicrocordiceps Szidat & Soria, 1957
Diphyllobothriumnorvegicum Vik, 1957
Geographic distribution. Holarctic (Scholz and Kuchta 2016).
Natural hosts. The first intermediate hosts are freshwater copepods. The second intermediate and paratenic hosts are many different freshwater fish. Definitive hosts are fish-eating birds, primarily gulls, and mammals, including wild and domestic canids, bears, and otters. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Kuchta et al. 2013).
Site in human host. Small intestine (Kuchta et al. 2013).
Dibothriocephalushians Diesing, 1850
Geographic distribution. Mediterranean and Circumboreal (Scholz and Kuchta 2016).
Natural hosts. The first intermediate hosts are presumed to be marine copepods. The second intermediate hosts are unknown, but presumed to be marine fish. Definitive hosts are seals. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Dibothriocephaluslatus (Linnaeus, 1758)
Diphyllobothriumamericanum Hall & Wigdor, 1918
Diphyllobothriumtungussicum Podyapolskaya & Gnedina, 1932
Diphyllobothriumskrjabini Plotnikoff, 1933
Geographic distribution. Holarctic, South America (Scholz and Kuchta 2016).
Natural hosts. The first intermediate hosts are freshwater copepods. The second intermediate and paratenic hosts are freshwater fish, including perch, pike, burbot, walleye, and pikeperch. Definitive hosts are fish-eating carnivores, including wild and domestic dogs and cats, bears, and mustelids. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz et al. 2009).
Site in human host. Small intestine (Scholz et al. 2009).
Dibothriocephalusnihonkaiensis (Yamane et al., 1886)
Diphyllobothriumgiljacicum Rutkevich, 1937
Diphyllobothriumklebanovskii Muratov & Posokov, 1988
Geographic distribution. Northern Pacific (Scholz and Kuchta 2016; Ikuno et al. 2018).
Natural hosts. First intermediate hosts are marine copepods. Second intermediate hosts are salmonid fish. Definitive hosts are bears, wild canids, and mink. Zoonotic in humans.
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Dibothriocephalusursi (Rausch, 1954)
Diphyllobothriumgonodo Yamaguti, 1942
Geographic distribution. Northern North America (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are marine copepods. Second intermediate hosts are salmonid fish, primarily sockeye salmon (Oncorhynchusnerka). Definitive hosts are bears. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Genus Diphyllobothrium Cobbold, 1858
Diphyllobothriumbalaenopterae (Lönnberg, 1892)
Krabbeagrandis Blanchard, 1894
Diplogonoporusfukuokaensis Kamo & Miyazaki, 1970
Geographic distribution. Worldwide (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are marine copepods. Second intermediate hosts are marine fish, including Japanese anchovy, Japanese sardine, and skipjack tuna. Definitive hosts are baleen whales. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Diphyllobothriumstemmacephalum Cobbold, 1858
Diphyllobothriumponticum Delyamure, 1971
Diphyllobothriumyonagoense Yamane et al., 1981
Geographic distribution. Northern Hemisphere (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are presumed to be marine copepods. Second intermediate hosts are unknown, but presumed to be marine fish. Definitive hosts are dolphins and porpoises. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Diphyllobothrium , incertae sedis:
Diphyllobothriumcordatum (Leuckart, 1863)
Geographic distribution. Circumpolar (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are presumed to be marine copepods. Second intermediate hosts are unknown, but presumed to be marine fish. Definitive hosts are seals and walrus. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Diphyllobothriumlanceolatum (Krabbe, 1865)
Geographic distribution. Circumpolar (Scholz and Kuchta 2016).
Natural hosts. First intermediate hosts are marine copepods. Second intermediate hosts are marine fish, including sardine cisco (Coregonussardinella). Definitive hosts are seals. Zoonotic in humans (Scholz and Kuchta 2016).
Route of infection. Ingestion of plerocercoids in infected fish (Scholz and Kuchta 2016).
Site in human host. Small intestine (Scholz and Kuchta 2016).
Genus Spirometra Faust et al., 1929
Spirometradecepiens (Diesing, 1850)
Geographic distribution. North and South America, Southeast Asia (Jeon et al. 2015; Jeon et al. 2018b).
Natural hosts. First intermediate hosts are believed to be freshwater copepods. Second intermediate hosts are believed to be freshwater fish and/or amphibians. Definitive hosts are wild and domestic cats; dogs may serve as reservoir hosts. Zoonotic in humans as dead-end hosts that harbor plerocercoid larvae (Jeon et al. 2015; Jeon et al. 2018b).
Route of infection. Ingestion of plerocercoids in infected paratenic or intermediate host; ingestion of water containing copepods infected with procercoids (Jeon et al. 2015; Jeon et al. 2018b).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS (Jeon et al. 2015; Jeon et al. 2018b).
Spirometraerinaceieuropaei (Rudolphi, 1819)
Geographic distribution. Europe, Asia, and Australia (Tang et al. 2017; Kuchta et al. 2021).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are amphibians, reptiles and mammals. Definitive hosts are believed to be wild and domestic canids and felids. Zoonotic in humans as dead-end hosts that harbor plerocercoid larvae (Tang et al. 2017; Kuchta et al. 2021).
Route of infection. Ingestion of plerocercoids in infected paratenic or intermediate host; ingestion of water containing copepods infected with procercoids (Lee et al. 1984; Tang et al. 2017).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS as plerocercoid larvae (spargana); rarely as adults in small intestine (Lee et al. 1984; Tang et al. 2017).
Spirometramansoni (Joyeux & Houdemer, 1928)
Geographic distribution. Southeast Asia (Hong et al. 2016).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are amphibians, while reptiles, birds, and pigs may serve as paratenic hosts. Definitive hosts are felids and canids. Zoonotic in humans as dead-end hosts that harbor plerocercoid larvae (Hong et al. 2016).
Route of infection. Ingestion of plerocercoids in infected paratenic or intermediate host; ingestion of water containing copepods infected with procercoids (Galan-Puchades 2019).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS (Galan-Puchades 2019).
Spirometramansonoides (Mueller, 1935)
Geographic distribution. North America (McHale et al. 2020).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are amphibians, reptiles, birds, small mammals. Definitive hosts are felids and canids. Zoonotic in humans as dead-end hosts that harbor plerocercoid larvae (McHale et al. 2020).
Route of infection. Ingestion of plerocercoids in infected paratenic or intermediate host; ingestion of water containing copepods infected with procercoids (Landero et al. 1991).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS (Landero et al. 1991).
Spirometraranarum (Gastaldi, 1854)
Geographic distribution. Africa, Southeast Asia (Jeon et al. 2018a; Saksirisampant et al. 2020).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are amphibians and reptiles. Definitive hosts are wild and domestic felids and canids. Zoonotic in humans as dead-end hosts that harbor plerocercoid larvae (Jeon et al. 2018a; Saksirisampant et al. 2020).
Route of infection. Ingestion of infected intermediate or paratenic host (Saksirisampant et al. 2020).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS (Saksirisampant et al. 2020).
Spirometra spp.
Geographic distribution. East Africa (Eberhard et al. 2015).
Natural hosts. Unknown (Eberhard et al. 2015).
Route of infection. Either ingestion of plerocercoids in undercooked intermediate or paratenic hosts, or water containing copepods infected with procercoids (Eberhard et al. 2015).
Site in human host. Skin and soft tissues (Eberhard et al. 2015).
Notes. Several infections with Spirometra sp. have been confirmed in South Sudan and sporadically in other East African countries. Molecular data have confirmed distinctiveness from other known zoonotic Spirometra spp., but no specific identification has been determined (Eberhard et al. 2015).
Diphyllobothriidae, incertae sedis:
Sparganumproliferum (Ilima, 1905)
Geographic distribution. Undefined (Mueller and Strano 1974).
Natural hosts. Unknown, currently known only from humans in which it is believed to be zoonotic (Mueller and Strano 1974).
Route of infection. Unknown, but presumed to be ingestion of infected intermediate or paratenic host (Mueller and Strano 1974).
Site in human host. Skin and soft tissues, pleural and peritoneal cavities, abdominal viscera, eye, CNS (Mueller and Strano 1974).
Notes. The name Sparganumproliferum is the name given to an enigmatic parasite of unknown affinities. To date, it is only known from its larval form from humans.
●●●●●●● Cyclophyllidea van Beneden in Braun, 1990
●●●●●●●● Dipylidiidae Stiles, 1896
Genus Dipylidium Leuckart, 1863
Microtaenia Sedgwick in Claus & Sedwick, 1884
Dipylidiumcaninum (Linnaeus, 1758)
Geographic distribution. Worldwide (Sapp and Bradbury 2020).
Natural hosts. Intermediate hosts are insects, primarily fleas (Ctenocephalides, Pulex) and lice (Trichodectes). Definitive hosts are wild and domestic felids and canids. Zoonotic in humans (Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected arthropod intermediate host (Cabello et al. 2011; Sapp and Bradbury 2020).
Site in human host. Small intestine (Cabello et al. 2011; Sapp and Bradbury 2020).
●●●●●●●● Hymenolepididae Ariola, 1899
Genus Hymenolepis Weinland, 1858
Hymenolepisdiminuta (Rudolphi, 1819)
Taeniaflavopunctata Weinland, 1858
Geographic distribution. Worldwide (Arai 1980).
Natural hosts. Intermediate hosts are insects, commonly granary beetles. Definitive hosts are rodents (primarily rats). Zoonotic in humans (Arai 1980).
Route of infection. Ingestion of cysticercoids infected insect intermediate host (Tiwari et al. 2014).
Site in human host. Small intestine (Tiwari et al. 2014).
Hymenolepishibernia Montgomery et al., 1987
Geographic distribution. Europe, Asia (Sargison et al. 2018).
Natural hosts. Intermediate hosts are beetles. Definitive hosts are mice in the genus Apodemus. Zoonotic in humans (Sargison et al. 2018).
Route of infection. Presumed ingestion of cysticercoids in infected insect intermediate host (Nkouawa et al. 2016).
Site in human host. Small intestine (Nkouawa et al. 2016).
Genus Rodentolepis Spasskii, 1954
Rodentolepismicrostoma (Dujardin, 1845)
Geographic distribution. Worldwide (Cunningham and Olson 2010).
Natural hosts. Intermediate hosts are insects, commonly granary beetles and fleas. Definitive hosts are fleas. Zoonotic in humans (Andreassen et al. 2004; Cunningham and Olson 2010).
Route of infection. Presumably, ingestion of cysticercoids in infected insect intermediate host (Macnish et al. 2003).
Site in human host. Small intestine (Macnish et al. 2003).
Notes. The few cases of H.microstoma in humans have been diagnosed by molecular detection in stool (Macnish et al. 2003).
Rodentolepisnana (Bilharz, 1851)
Hymenolepisfraterna Stiles, 1906
Geographic distribution. Worldwide (Sataeva et al. 2018).
Natural hosts. Intermediate hosts are insects, commonly granary beetles and fleas. Definitive hosts are rodents. Zoonotic in humans, although human-to-human transmission can occur (Sataeva et al. 2018).
Route of infection. Ingestion of cysticercoids in infected insect intermediate host; ingestion of eggs on fecally contaminated fomites (Thompson 2015; Sataeva et al. 2018).
Site in human host. Small intestine (Thompson 2015; Sataeva et al. 2018).
●●●●●●●● Taeniidae Ludwig, 1886
Genus Echinococcus Rudolphi, 1801
Echinococcuscanadensis Webster & Cameron, 1961
Echinococcusgranulosusborealis Williams & Sweatman, 1863
Echinococcus G6, camel-pig strain
Echinococcus G7, camel-pig strain
Echinococcus G8, American cervid strain
Echinococcus G10, Fennoscandian strain
Geographic distribution. North America, Europe, Middle East, China, east Africa (Romig et al. 2015; Hua et al. 2019).
Natural hosts. Intermediate hosts are camels, pigs, goats, and deer. Definitive hosts are wild and domestic canids. Zoonotic in humans as dead-end hosts harboring larval cysts (Romig et al. 2015; Hua et al. 2019).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with dog feces (Romig et al. 2015).
Site in human host. Disseminated infection, common sites of colonization are liver, lung, brain, bone (Romig et al. 2015).
Echinococcusequinus Willams & Sweatman, 1963
Echinococcus G4, horse strain
Geographic distribution. Europe, North Africa, Middle East (Romig et al. 2015).
Natural hosts. Intermediate hosts are horses. Definitive hosts are wild and domestic canids. Zoonotic in humans as dead-end hosts harboring larval cysts (Romig et al. 2015).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Romig et al. 2015; Kim et al. 2020).
Site in human host. Disseminated infection, common sites of colonization are liver, lung, brain, bone (Kim et al. 2020).
Echinococcusgranulosus (Batsch, 1796)
Echinococcusminimus Cameron, 1926
Echinococcuslongimanubrius Cameron, 1926
Echinococcuscameroni Ortlepp, 1934
Echinococcuslycaontis Ortlepp, 1934
Echinococcusintermedius Lopez-Neyra & Soler Planas, 1943
Echinococcuspatagonicus Szidat, 1960
Echinococcuscepanzoi Szidat, 1971
Echinococcus G1, sheep-buffalo strain
Echinococcus G2, sheep-buffalo strain
Echinococcus G3, sheep-buffalo strain
Geographic distribution. Worldwide (Eckert and Deplazes 2004; Romig et al. 2015).
Natural hosts. Intermediate hosts are primarily sheep, goats, cattle, and buffalo. Definitive hosts are wild and domestic canids. Zoonotic in humans as dead-end hosts harboring larval cysts (Eckert and Deplazes 2004; Romig et al. 2015).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Eckert and Deplazes 2004; Romig et al. 2015).
Site in human host. Disseminated infection, common sites of colonization are liver, lung, brain, bone (Eckert and Deplazes 2004; Romig et al. 2015).
Echinococcusmultilocularis (Leuckart, 1863)
Echinococcussibiricensis Rausch & Schiller, 1964
Echinococcusrussicensis Tang et al., 2007
Geographic distribution. Europe, Asia, North America (Eckert and Deplazes 2004; Conraths and Deplazes 2015).
Natural hosts. Intermediate hosts are rodents, primarily voles. Definitive hosts are wild canids, primarily red fox (Vulpesvulpes); raccoon dogs, domestic dogs, and domestic cats may serve as reservoir hosts. Zoonotic in humans as dead-end hosts harboring larval cysts (Conraths and Deplazes 2015; Eckert and Deplazes 2004).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Eckert and Deplazes 2004; Conraths and Deplazes 2015).
Site in human host. Liver, with dissemination to other organs, such as lung, heart, brain, bone (Eckert and Deplazes 2004; Conraths and Deplazes 2015).
Echinococcusoligarthra Diesing, 1863
Echinococcuscruzi Brumpt & Joyeux, 1924
Echinococcuspampeanus Szidat, 1967
Geographic distribution. South America (D’Alessandro and Rausch 2008).
Natural hosts. Intermediate hosts are rodents and marsupials. Definitive hosts are wild felids. Zoonotic in humans as dead-end hosts harboring larval cysts (D’Alessandro and Rausch 2008).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with felid feces (D’Alessandro and Rausch 2008).
Site in human host. Liver, peritoneal and pleural cavities, with dissemination to other organs (D’Alessandro and Rausch 2008).
Echinococcusortleppi Lopez-Neyra & Soler Planas, 1943
Echinococcus G5, cattle strain
Geographic distribution. Africa, Europe, India, South America (Romig et al. 2015).
Natural hosts. Intermediate hosts are primarily bovids. Definitive hosts are wild and domestic canids. Zoonotic in humans as dead-end hosts harboring larval cysts (Romig et al. 2015).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Romig et al. 2015).
Site in human host. Disseminated infection, common sites of colonization are liver, lung, brain, bone (Romig et al. 2015).
Echinococcusvogeli Rausch & Berstein, 1972
Geographic distribution. South America (D’Alessandro and Rausch 2008).
Natural hosts. Intermediate hosts are rodents, primarily paca (Cuniculuspaca). Definitive hosts are bush dogs (Speothosvenaticus). Zoonotic in humans as dead-end hosts harboring larval cysts (D’Alessandro and Rausch 2008).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with bush dog feces (D’Alessandro and Rausch 2008).
Site in human host. Liver, peritoneal and pleural cavities, with dissemination to other organs (D’Alessandro and Rausch 2008).
Genus Hydatigera Lamarck, 1816
Hydatigerataeniaeformis (Batsch, 1786)
Cysticercusfasciolaris Rudolphi, 1808
Geographic distribution. Worldwide (Nakao et al. 2013; Guo 2020).
Natural hosts. Intermediate hosts are primarily rodents and lagomorphs. Definitive hosts are felids. Zoonotic in humans (Nakao et al. 2013; Guo 2020).
Route of infection. Unknown
Site in human host. Small intestine, liver (Stĕrba and Barus 1976; Guo 2020).
Genus Taenia Linnaeus, 1758
Taeniabrauni Setti, 1897
Geographic distribution. Africa (Deplazes et al. 2019).
Natural hosts. Intermediate hosts are rodents and non-human primates. Definitive hosts are canids and genets. Zoonotic in humans as dead-end hosts harboring larval cysts (Deplazes et al. 2019).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Lescano and Zunt 2013).
Site in human host. Skin and soft tissues, eyes (Vanderick et al. 1964; Lescano and Zunt 2013; Deplazes et al. 2019).
Notes.Taeniabrauni is often considered a subspecies or synonym of T.serialis.
Taeniacrassiceps (Zeder, 1800)
Taeniahyperborea von Linstow, 1905
Geographic distribution. Northern Hemisphere (Ntoukas et al. 2013).
Natural hosts. Intermediate hosts are rodents. Definitive hosts are canids, primarily foxes Zoonotic in humans as dead-end hosts harboring larval cysts (Freeman 2011; Ntoukas et al. 2013).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Ntoukas et al. 2013; Tappe et al. 2016a).
Site in human host. Skin and soft tissues, eyes, CNS (Ntoukas et al. 2013; Tappe et al. 2016a).
Taeniaglomeratus (Railliett & Henry, 1915)
Geographic distribution. Africa (Deplazes et al. 2019).
Natural hosts. Intermediate hosts are rodents. Definitive hosts are canids and genets. Zoonotic in humans as dead-end hosts harboring larval cysts (Lescano and Zunt 2013; Deplazes et al. 2019).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Lescano and Zunt 2013; Deplazes et al. 2019).
Site in human host. Eyes (Lescano and Zunt 2013; Deplazes et al. 2019).
Notes.Taeniaglomeratus is often considered a subspecies or synonym of T.serialis.
Taeniamartis (Zeder, 1803)
Geographic distribution. North America, Europe (Brunet et al. 2015).
Natural hosts. Intermediate hosts include rodents. Definitive hosts are mustelids and foxes. Zoonotic in humans has a dead-end host harboring larval cysts (Eberwein et al. 2013; Brunet et al. 2015; Deplazes et al. 2019).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with feces of definitive host (Brunet et al. 2015; Deplazes et al. 2019).
Site in human host. Skin and soft tissues, CNS, eyes (Eberwein et al. 2013; Brunet et al. 2015; Deplazes et al. 2019).
Taeniamulticeps Leske, 1790
Geographic distribution. Worldwide (Varcasia et al. 2015).
Natural hosts. Intermediate hosts are ungulates, primarily sheep. Definitive hosts are canids, primarily foxes. Zoonotic in humans as dead-end hosts harboring larval cysts (Varcasia et al. 2015; Deplazes et al. 2019).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Deplazes et al. 2019).
Site in human host. Skin and soft tissues, CNS (Deplazes et al. 2019).
Taeniasaginata Goeze, 1782
Taeniaconfusa Ward, 1896
Taeniaafricana von Linstow, 1900
Taeniahominis von Linstow, 1904
Geographic distribution. Worldwide (Hoberg 2002; Braae et al. 2018).
Natural hosts. Intermediate hosts are cattle. Definitive hosts are humans (Braae et al. 2018; Hoberg 2002).
Route of infection. Ingestion of cysticercoids in infected cattle (Braae et al. 2018).
Site in human host. Small intestine (Braae et al. 2018).
Taeniaserialis Gervais, 1847
Multicepsradians Joyeux et al., 1922
Geographic distribution. Worldwide; highest prevalence in Africa (Schneider-Crease et al. 2017).
Natural hosts. Intermediate hosts include rabbits, rodents, cattle, sheep, goats. Definitive hosts are wild and domestic canids. Zoonotic in humans as dead-end hosts harboring larval cysts (Schneider-Crease et al. 2017).
Route of infection. Ingestion of eggs in food, water, fomites contaminated with canid feces (Tappe et al. 2016a).
Site in human host. CNS (Tappe et al. 2016a).
Taeniasolium Linnaeus, 1758
Cysticercuscellulosae Gmelin, 1790
Geographic distribution. Worldwide (Garcia et al. 2003; Nakao et al. 2002; Coral-Almeida et al. 2015).
Natural hosts. Intermediate hosts are pigs. Definitive hosts are humans, although in cases of cysticercosis humans function as dead-end intermediate hosts (Garcia et al. 2003; Coral-Almeida et al. 2015).
Route of infection. Ingestion of cysticercoids in infected pigs (taeniasis); ingestion of eggs in food, water, fomites contaminated with human feces (cysticercosis) (Garcia et al. 2003).
Site in human host. Small intestine (taeniasis); disseminated infection with predilection for CNS (cysticercosis) (Garcia et al. 2003).
Taeniasuihominis Mathison et al., 2021
Taeniaasiatica Eom & Rim, 1993
Taeniasaginataasiatica Eom & Rim, 1993
Taeniaasiaticus Eom et al., 2020
Geographic distribution. East Asia (Ale et al. 2014).
Natural hosts. Intermediate hosts are pigs. Definitive hosts are humans (Eom and Rim 1993; Ale et al. 2014).
Route of infection. Ingestion of cysticerci in infected pigs (Ale et al. 2014; Eom and Rim 1993).
Site in human host. Small intestine (Eom and Rim 1993; Ale et al. 2014).
Genus VersteriaNakao et al., 2013
Geographic distribution. Europe, Central Asia, North America (Nakao et al. 2013; Deplazes et al. 2019).
Natural hosts. Intermediate hosts are rodents; non-human primates can be incidental hosts. Definitive hosts are mustelids. Zoonotic in humans (Nakao et al. 2013; Deplazes et al. 2019).
Route of infection. Presumably by the ingestion of eggs in food, water, fomites contaminated with feces of definitive host (Deplazes et al. 2019).
Site in human hose. Various organs, disseminated infection (Barkati et al. 2018; Lehman et al. 2019).
Notes. Human and primate Versteria infections have not been identified to species level but bear close genetic resemblance to isolates from North American mink and are somewhat similar to isolates of V.mustelae (Gmelin, 1790) from European mink (Lee et al. 2016; Lehman et al. 2019).
●●●●●●●● Anoplocephalidae Cholodkovsky, 1902
Genus Bertiella Stiles & Hassall, 1902
Bertia Blanchard, 1891
Bertiellamucronotata (Meyner, 1895)
Geographic distribution. South America, Caribbean (Sapp and Bradbury 2020).
Natural hosts. First intermediate hosts are oribatid mites. Definitive hosts are New World monkeys. Zoonotic in humans (Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected mite intermediate host (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
Bertiellastuderi (Blanchard, 1891)
Geographic distribution. Africa, Asia (Sapp and Bradbury 2020).
Natural hosts. First intermediate hosts are oribatid mites. Definitive hosts are Old World monkeys and non-human apes. Zoonotic in humans (Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected mite intermediate host (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
Genus Inermicapsifer Janicki, 1910
Inermicapsifermadagascariensis (Davaine, 1870)
Acanthocephalaarvicanthidis Kofend, 1917
Raillietinacubensis Kouri, 1938
Geographic distribution. Sub-Saharan Africa, South America, West Indies, Southeast Asia (Goldsmid and Muir 1972; Sapp and Bradbury 2020).
Natural hosts. Intermediate hosts are not known, but presumed to be terrestrial arthropods. Definitive hosts are rodents and hyraxes. Zoonotic in humans (Goldsmid and Muir 1972; Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected arthropod intermediate host (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
Genus Mathevotaenia Akhumyan, 1946
Mathevotaeniasymmetrica (Baylis, 1927)
Geographic distribution. Europe, Asia (Lamon and Greer 1986).
Natural hosts. Intermediate hosts are suspected as being arthropods. Definitive hosts are rodents. Zoonotic in humans (Lamon and Greer 1986).
Route of infection. Presumably, ingestion of cysticercoids in infected arthropod intermediate host (Lamon and Greer 1986).
Site in human host. Small intestine (Lamon and Greer 1986).
Genus Moniezia Blanchard, 1891
Monieziaexpansa (Rudolphi, 1810)
Geographic distribution. Worldwide (single human case from Egypt) (Elliott 1986; el-Shazly et al. 2004).
Natural hosts. Intermediate hosts are mites. Definitive hosts are sheep, goats, cattle. Zoonotic in humans (Elliott 1986; el-Shazly et al. 2004).
Route of infection. Presumably, ingestion of cysticercoids in infected arthropod intermediate host (el-Shazly et al. 2004).
Site in human host. Small intestine (el-Shazly et al. 2004).
●●●●●●●● Davaineidae Braun, 1900
Genus Raillietina Fuhrman, 1920
Raillietinacelebensis (Janicki, 1902)
Taeniaasiatica von Linstow, 1891
Taeniaformosana Akashi, 1916
Raillietinafunerebris Meggitt & Subramanian, 1927
Raillietinagarrisoni Tubangui, 1931
Raillietinasinensis Hsu, 1935
Raillietinamurium Joyeux & Baer, 1938
Geographic distribution. Asia, Australia (Baer and Sandars 1956; Sapp and Bradbury 2020).
Natural hosts. Intermediate hosts are invertebrates, including insects (primarily ants and beetles) and terrestrial mollusks. Definitive hosts are rodents and shrews. Zoonotic in humans (Baer and Sandars 1956; Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected arthropod intermediate host (Baer and Sandars 1956; Sapp and Bradbury 2020).
Site in human host. Small intestine (Baer and Sandars 1956; Sapp and Bradbury 2020).
Raillietinademerariensis (Daniels, 1895)
Raillietinaquitensis Leon, 1935
Raillietinabrumpti Doilfus, 1939
Raillietinaequatoriensis Dollfus, 1939
Raillietinaleoni Dollfus, 1939
Raillietinaluisaleoni Dollfus, 1939
Raillietinahalli Perez-Vigueras, 1934
Geographic distribution. South America, Caribbean (Baer and Sandars 1956; Sapp and Bradbury 2020).
Natural hosts. Intermediate hosts are invertebrates, including insects (primarily ants and beetles) and terrestrial mollusks. Definitive hosts are rodents; non-human primates may serve as reservoir hosts. Zoonotic in humans (Baer and Sandars 1956; Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected arthropod intermediate host (Baer and Sandars 1956; Sapp and Bradbury 2020).
Site in human host. Small intestine (Baer and Sandars 1956; Sapp and Bradbury 2020).
Raillietinasiriraji Chandler & Pradatsundarasar, 1957
Geographic distribution. Thailand (Sapp and Bradbury 2020).
Natural hosts. Intermediate hosts are invertebrates, including insects (primarily ants and beetles). Definitive hosts are rodents. Zoonotic in humans (Sapp and Bradbury 2020).
Route of infection. Ingestion of cysticercoids in infected arthropod intermediate host (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
●●●●●●●● Mesocestoididae Fuhrmann, 1907
Genus Mesocestoides Valliant, 1863
Mesocestoideslineatus (Goeze, 1782)
Geographic distribution. Europe and Asia (Sapp and Bradbury 2020).
Natural hosts. The complete life cycle and presumed number of hosts is not completely understood. The presumed first intermediate host is believed to be an arthropod. The second intermediate hosts are a variety of vertebrates, including small mammals, birds, reptiles, and amphibians. Definitive hosts are carnivores, including foxes, wolves, raccoon dogs, and European badgers. Zoonotic in humans (Padgett and Boyce 2004; Sapp and Bradbury 2020).
Route of infection. Unknown; presumed to be ingestion of tetrathyridia in meat and viscera of infected second intermediate hosts (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
Mesocestoidesvariabilis Mueller, 1928
Geographic distribution. North America (Sapp and Bradbury 2020).
Natural hosts. The complete life cycle and presumed number of hosts is not completely understood. The presumed first intermediate host is believed to be an arthropod. The second intermediate hosts are a variety of vertebrates, including small mammals, birds, reptiles, and amphibians. Definitive hosts include wild and domestic canids and felids, mustelids, and opossums. Zoonotic in humans (Padgett and Boyce 2004; Sapp and Bradbury 2020).
Route of infection. Unknown; presumed to be ingestion of tetrathyridia in meat and viscera of infected second intermediate hosts (Sapp and Bradbury 2020).
Site in human host. Small intestine (Sapp and Bradbury 2020).
●●●●● Trematoda Rudolphi, 1808
●●●●●● Digenea Carus, 1863
●●●●●●● Diplostomida Olson et al., 2003
●●●●●●●● Diplostomata Olson et al., 2003
●●●●●●●●● Brachylaeimidae Joyeux & Foley, 1930
Genus Brachylaeima Dujardin, 1843
Brachylaeimacribbi Butcher & Grove, 2001
Geographic distribution. Australia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are terrestrial snails in the genus Theba. Second intermediate hosts are land snails in the genus Cernualla. Definitive hosts include a variety of birds, mammals, and reptiles. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected snail intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Cyathocotylidae Mühling, 1898
Genus Prohemistomum Odhner, 1913
Prohemistomumvivax (Sonsino, 1892)
Geographic distribution. Europe, North Africa, Middle East (Nasr 1941; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Cleopatra. Second intermediate hosts are various brackish water and freshwater fish. Definitive hosts are felids, canids, and birds. Zoonotic in humans (Nasr 1941; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate hosts (Nasr 1941; Chai and Jung 2020)
Site in human host. Small intestine (Nasr 1941; Chai and Jung 2020).
●●●●●●●●● Diplostomidae Poirier, 1886
Genus Alaria Schrank, 1788
Alariaamericana Hall & Wigdor, 1918
Geographic distribution. North America (Möhl et al. 2009).
Natural hosts. First intermediate hosts are snails in the genera Planorbis, Heliosoma, Lymnea, and Anisus. Second intermediate hosts are amphibians; many vertebrate animals can serve as paratenic hosts. Definitive hosts are carnivores. Zoonotic in humans (Möhl et al. 2009).
Route of infection. Ingestion of metacercariae in undercooked game meat (Möhl et al. 2009).
Site in human host. Subcutaneous tissues, eyes, lungs, disseminated infections (Freeman et al. 1976; Möhl et al. 2009).
Genus Fibricola Dubois, 1932
Fibricolacratera (Barker & Noll, 1915)
Geographic distribution. North America (Hoffman 1955; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Physa. Second intermediate hosts are amphibians. Definitive hosts are rodents and shrews. Zoonotic in humans (Hoffman 1955; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected amphibian intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Neodiplostomum Railliet, 1919
Neodiplostomumseoulense Seo et al., 1964
Geographic distribution. China, South Korea (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Hippeutis and Segmentina. Second intermediate hosts are amphibians; snakes can serve as paratenic hosts. Definitive hosts are rodents and humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected reptile and amphibian intermediate and paratenic hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Strigeidae Railliet, 1919
Genus Cotylurus Szidat, 1928
Cotylurusjaponicus Ishii, 1932
Geographic distribution. Central and Southeast Asia, Russia, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown but hypothesized to be freshwater snails. Second intermediate hosts are unknown but presumed to be freshwater snails. Definitive hosts are ducks. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected insect intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Schistosomatidae Stiles & Hassall, 1898
Genus Schistosoma Weinland, 1858
Schistosomabovis (Bilharz, 1852)
Geographic distribution. Southern Europe, Middle East, South Asia, Africa (Christensen et al. 1983).
Natural hosts. First intermediate hosts are snails in the genus Bulinus. Definitive hosts are ruminants, primarily cattle. Zoonotic in humans (Christensen et al. 1983).
Route of infection. Penetration of skin by free-swimming cercariae
Site in human host. Mesenteric veins of the large intestine (Chunge et al. 1986; Mouchet et al. 1988)
Notes. Human infections with hybrids of S.bovis and S.haematobium have been confirmed using molecular methods (Oleaga et al. 2019).
Schistosomaguineensis Pagès et al., 2003
Schistosomaintercalatum, Guinea strain
Geographic distribution. West Africa (Webster et al. 2006).
Natural hosts. First intermediate hosts are snails in the genus Bulinus. Definitive hosts are humans, rodents, ruminants (Webster et al. 2006).
Route of infection. Penetration of skin by free-swimming cercariae (Webster et al. 2006).
Site in human host. Mesenteric veins of the large intestine (Webster et al. 2006).
Schistosomahaematobium (Bilharz, 1852)
Geographic distribution. Africa, isolated regions of the Middle East (Colley et al. 2014; Gautret et al. 2015).
Natural hosts. First intermediate hosts are snails in the genus Bulinus. Definitive hosts are humans (Colley et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Colley et al. 2014).
Site in human host. Venous plexus of the urinary bladder (Colley et al. 2014).
Notes. Human infection of hybrids of S.haematobium and S.bovis have been documented in Corsica, France (Oleaga et al. 2019).
Schistosomaintercalatum Fisher, 1934
Geographic distribution. Democratic Republic of the Congo (Webster et al. 2006; Colley et al. 2014).
Natural hosts. First intermediate hosts are snails in the genus Bulinus. Definitive hosts are humans, rodents, ruminants (Colley et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Colley et al. 2014).
Site in human host. Mesenteric veins of the large intestine (Colley et al. 2014).
Schistosomajaponicum (Katsurada, 1904)
Geographic distribution. China, Philippines, Indonesia (Sulawesi) (Colley et al. 2014).
Natural hosts. First intermediate hosts are snails in the genus Oncomelania. Definitive hosts include a variety of mammals, including canids, felids, pigs, ruminants, rodents, and humans (Colley et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Colley et al. 2014).
Site in human host. Mesenteric veins of the small and large intestine (Colley et al. 2014).
Schistosomamansoni Sambon, 1907
Geographic distribution. Sub-Saharan Africa, South America, Caribbean, parts of the Arabian Peninsula (Colley et al. 2014).
Natural hosts. First intermediate hosts are snails in the genus Biomphalaria. Definitive hosts are humans, occasionally non-human primates (Colley et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Colley et al. 2014).
Site in human host. Mesenteric veins of the large intestine (Colley et al. 2014).
Schistosomamattheei Veglia & LeRoux, 1929
Geographic distribution. Africa, Middle East (Christensen et al. 1983).
Natural hosts. First intermediate hosts are snails in the genus Bulinus. Definitive hosts are wild and domestic ruminants. Zoonotic in humans (Christensen et al. 1983).
Route of infection. Penetration of skin by free-swimming cercariae (Christensen et al. 1983).
Site in human host. Presumed to be venous plexus of the urinary bladder (Wolmarans et al. 1990; Cnops et al. 2020).
Notes. Reports of patent, egg-producing human infections with S.mattheei are most likely a result of hybridization of this species with S.haematobium. Dead-end acute infections with S.mattheei × S.haematobium have been confirmed using molecular methods (Kruger and Evans 2009; Cnops et al. 2020).
Schistosomamekongi Voge et al., 1978
Geographic distribution. Mekong River Valley of Cambodia and Laos (Colley et al. 2014).
Natural hosts. First intermediate host is the snail Neotriculaaperta. Definitive hosts include a variety of mammals, including canids, felids, pigs, ruminants, rodents, and humans (Colley et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Colley et al. 2014).
Site in human host. Mesenteric veins of the large intestine (Colley et al. 2014).
Cercarial dermatitis
Many species of avian, and some mammalian, schistosomes cause a limited cutaneous reaction in humans referred to as cercarial dermatitis (or “swimmer’s itch”). The identity of causative agents is typically inferred via environmental investigations following outbreaks and may or may not be identified to species level; only the major genera are listed here:
Genus Anserobilharzia Brandt et al., 2013
Geographic distribution. Northern Hemisphere (Brant et al. 2013).
Natural hosts. Intermediate hosts are freshwater snails in the family Planorbidae. Definitive hosts are charadriiform birds. Zoonotic in humans (Brant et al. 2013; Horák et al. 2015).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Austrobilharzia Johnston, 1917
Geographic distribution. Northern Hemisphere, Australia (Farley 1971).
Natural hosts. Intermediate hosts are freshwater snails in the family Planorbidae. Definitive hosts are charadriiform birds. Zoonotic in humans (Farley 1971).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Bilharziella Looss, 1899
Geographic distribution. Europe (Prüter et al. 2017).
Natural hosts. Intermediate hosts are freshwater snails in the family Planorbidae. Definitive hosts are waterfowl and other wading birds. Zoonotic in humans (Prüter et al. 2017).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Bivitellobilharzia Vogel & Minning, 1940
Geographic distribution. Africa, Asia (Devkota et al. 2014).
Natural hosts. Snail intermediate hosts are unknown. Definitive hosts are elephants and rhinoceroses. Zoonotic in humans (Devkota et al. 2014).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Gigantobilharzia Odhner, 1910
Geographic distribution. North America (McDonald 1981).
Natural hosts. Intermediate hosts are freshwater snails in the family Physidae. Definitive hosts are passerine birds. Zoonotic in humans (McDonald 1981).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Heterobilharzia Price, 1929
Geographic distribution. North America (Graham et al. 2021).
Natural hosts. Intermediate hosts are freshwater snails in the family Lymnaeidae. Definitive hosts are various mammals, including carnivores and marsupials. Zoonotic in humans (Graham et al. 2021).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Ornithobilharzia Odhner, 1912
Geographic distribution. Worldwide (Farley 1971)
Natural hosts. Intermediate hosts are marine snails in the family Batillaridae. Definitive hosts are various birds and mammals. Zoonotic in humans (Farley 1971).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
Genus Trichobilharzia Skrjabin & Zakharow, 1920
Geographic distribution. Worldwide (Horák et al. 2002).
Natural hosts. Intermediate hosts are freshwater snails in the families Lymnaeidae and Physidae. Definitive hosts are waterfowl. Zoonotic in humans (Horák et al. 2002).
Route of infection. Penetration of skin by free-swimming cercariae (Horák et al. 2015).
Site in human host. Skin (Horák et al. 2015).
●●●●●●● Plagiorchiida La Rue, 1957
●●●●●●●● Bucephalata La Rue, 1926
●●●●●●●●● Gymnophallidae Odhner, 1905
Genus Gymnophalloides Fujita, 1925
Gymnophalloidesseoi Chai et al., 2003
Geographic distribution. South Korea (Lee and Chai 2001; Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are oysters in the genus Crassostrea. Definitive hosts are oystercatchers (Haematopus). Zoonotic in humans (Lee and Chai 2001; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected oyster intermediate hosts (Lee and Chai 2001; Chai and Jung 2020),
Site in human host. Small intestine (Lee and Chai 2001; Chai and Jung 2020).
●●●●●●●● Echinostomata La Rue, 1926
●●●●●●●●● Himasthlidae Odhner, 1910
Genus Acanthoparyphium Dietz, 1909
Acanthoparyphiumtyosenense Yamaguti, 1939
Geographic distribution. Korea, Japan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are marine gastropods. The second intermediate hosts are brackish water bivalves. Definitive hosts are ducks. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected bivalves (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Genus Himasthla Dietz, 1909
Himasthlamuehlensi Vogel, 1933
Geographic distribution. North America, Colombia (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown, presumed to be marine gastropods. Second intermediate hosts are presumed to be marine clams and mussels. Definitive hosts are birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected mollusk intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
●●●●●●●●● Echinochasmidae Odhner, 1910
Genus Echinochasmus Dietz, 1909
Echinochasmuscaninus (Verma, 1935)
Geographic distribution. Southeast Asia, India (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are freshwater fish in the genus Macropodus. Definitive hosts are wild and domestic canids. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinochasmusfujianensis Chen, in Chen et al., 1992
Geographic distribution. China (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Bellamya Second intermediate hosts are freshwater fish in the genera Pseudorasbora and Cyprinus. Definitive hosts are wild and domestic canids and felids, pigs, and rodents. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinochastmusjaponicus Tanabe, 1926
Geographic distribution. Southeast Asia, Japan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails, including the genus Parafossarulis. Second intermediate hosts are various freshwater fish. Definitive hosts are felids, insectivores, and birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinochasmusjiufoensis Liang & Ke, 1988
Geographic distribution. China (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are presumed to be freshwater fish or mollusks. Definitive hosts are felids, canids, and pigs. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate host (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinochasmusliliputanus (Looss, 1896)
Geographic distribution. China, Middle East, North Africa (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Parafossarulus. Second intermediate hosts are freshwater fish in the genera Pseudorasbora and Carassius. Definitive hosts are felids, canids, raccoons, and badgers. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate fish host or water contaminated with metacercariae (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinochasmusperfoliatus (Ratz, 1908)
Geographic distribution. Southeast Asia, Russia, Europe, North Africa (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are various freshwater snails (Parafossarulus, Bithynia, Lymnaea). Second intermediate hosts are various freshwater fish (Zacco, Carassius, Pseudorasbora). Definitive hosts are felids, canids, pigs, and birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
●●●●●●●●● Echinostomatidae Looss, 1899
Genus Artyfechinostomum Lane, 1915
Artyfechinostomummalayanum (Leiper, 1911)
Geographic distribution. Southeast Asia (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Indoplanorbis and Gyraulus. Second intermediate hosts are several freshwater snails. Definitive hosts include pigs, rodents, shrews, felids, canids. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected snail intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Artyfechinostomumoraoni Bandyopadhyay et al., 1989
Geographic distribution. India (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genus Lymnaea. Second intermediate hosts and definitive hosts are unknown; presumed zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Artyfechinostomumsufratyfex Lane, 1915
Cercariamehrai Faruqui, 1930
Geographic distribution. India, Vietnam (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genera Indoplanorbis and Lymnaea. Second intermediate hosts include freshwater snails, fish, and amphibians. Definitive hosts are pigs, canids, and rodents. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Genus Echinoparyphium Dietz, 1909
Echinoparyphiumrecurvatum (von Linstow, 1873)
Geographic distribution. North America, Europe, North Africa, Middle East, Central and Southeast Asia (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genera Physa and Lymnaea. Second intermediate hosts include freshwater snails and amphibians. Definitive hosts are canids and rodents. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Genus Echinostoma Rudolphi, 1809
Echinostomaaegyptica Khalil & Abaza, 1924
Geographic distribution. North Africa, Middle East, Southeast Asia, Japan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First and second intermediate hosts are unknown. Definitive hosts are rats. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomaangustitestes Wang, 1977
Geographic distribution. China (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are presumed to be freshwater snails. Second intermediate hosts are freshwater fish. Definitive hosts are dogs and livestock. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomacinetorchis Ando & Ozaki, 1923
Geographic distribution. Southeast Asia, Japan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genera Hippeutis and Segmentina. Second intermediate hosts include freshwater snails, fish (Misgurnus), and amphibians. Definitive hosts are rats. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomailocanum (Garrison, 1908)
Geographic distribution. Central and Southeast Asia (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genera Gyraulus and Hippeutis. Second intermediate hosts include freshwater snails in the genera Pila and Vivaparus. Definitive hosts are rats and canids. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected snail intermediate hosts(Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomalindoense Sandground & Bonne, 1940
Geographic distribution. Europe, Southeast Asia, South America (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are several genera of freshwater snails. Second intermediate hosts include freshwater snails and mussels. Definitive hosts include a variety of mammals and birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected mollusk intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomamacrorchis Ando & Ozaki, 1923
Geographic distribution. Southeast Asia, Japan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genera Segmentina and Gyraulus. Second intermediate hosts include freshwater snails (Segmentina) and amphibians. Definitive hosts are rodents and wading birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine(Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomaparaensei Lie & Basch, 1967
Geographic distribution. Australia, Brazil (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First and second intermediate hosts are snails in the genus Biomphalaria. Definitive hosts are rats. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected snail intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Echinostomarevolutum (Froelich, 1802)
Geographic distribution. Europe, Russia, Middle East, Central and Southeast Asia, North America (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts include several genera of freshwater snails. Second intermediate hosts include freshwater snails and clams, and amphibians. Definitive hosts are felids, canids, rodents, and birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Notes. Numerous nominal species are considered part of the “E.revolutum complex” or the “37-collar-spined Echinostoma complex”; taxonomic resolution of species within this group is an area of ongoing investigation.
Genus Hypoderaeum Dietz, 1909
Hypoderaeumconoideum (Bloch, 1782)
Geographic distribution. Southeast Asia, Japan, Europe, North and Central America (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts include several genera of freshwater snails. Second intermediate hosts include freshwater snails and amphibians. Definitive hosts are birds. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Genus Isthmiophora Lühe, 1909
Isthmiophorahortensis (Asada, 1926)
Geographic distribution. China, Japan, Korea (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts include freshwater snails in the genera Lymnaea and Radix. Second intermediate hosts include several genera of freshwater fish. Definitive hosts are felids, canids, and rodents. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
Isthmiophoramelis (Schrank, 1788)
Geographic distribution. Europe, USA, Taiwan (Toledo and Esteban 2016; Chai and Jung 2020).
Natural hosts. First intermediate hosts freshwater snails in the genus Lymnaea. Second intermediate hosts are freshwater fish and amphibians. Definitive hosts are canids, mustelids, hedgehogs, and rodents. Zoonotic in humans (Toledo and Esteban 2016; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Toledo and Esteban 2016; Chai and Jung 2020).
Site in human host. Small intestine (Toledo and Esteban 2016; Chai and Jung 2020).
●●●●●●●●● Fasciolidae Railliet, 1895
Genus Fasciola Linnaeus, 1758
Fasciolagigantica Cobbold, 1855
Geographic distribution. Africa, Middle East, Southeast Asia, Japan (Tolan 2011; Phalee et al. 2015).
Natural hosts. First intermediate hosts are freshwater snails in the genus Lymnaea. Second intermediate hosts are aquatic plants. Definitive hosts are primarily sheep, also cattle, buffalo, goats, pigs. Zoonotic in humans (olan 2011; Phalee et al. 2015).
Route of infection. Ingestion of metacercariae on contaminated aquatic vegetation (olan 2011; Phalee et al. 2015).
Site in human host. Biliary ducts; ectopic migration to skin, brain (olan 2011; Phalee et al. 2015).
Fasciolahepatica Linnaeus, 1758
Geographic distribution. Worldwide; hot spots of endemicity for human infection include the Bolivian Altiplano, Ecuador, Peru, Cuba, Portugal, Spain, Turkey, North Africa (Nile Delta), Iran, Vietnam (Tolan 2011).
Natural hosts. First intermediate hosts are freshwater snails, particularly members of the genera Galba, Fossaria, and Pseudosuccinea. Second intermediate hosts are aquatic plants. Definitive hosts include primarily cattle and buffalo, also sheep, goats, and deer. Zoonotic in humans (Tolan 2011).
Route of infection. Ingestion of metacercariae on contaminated aquatic vegetation (Tolan 2011).
Site in human host. Biliary ducts; ectopic migration to skin, brain (Tolan 2011).
Genus Fasciolopsis Looss, 1899
Fasciolopsisbuski (Lankester in Küchenmeister, 1857)
Distomarathouisi Poirier, 1887
Fasciolopsisfuelleborni Rodenwadt, 1909
Fasciolopsisgoddardi Ward, 1910
Geographic distribution. Central and Southeast Asia (Sah et al. 2019; Chai and Jung 2020).
Natural hosts. First intermediate hosts are several genera of freshwater snails, especially the genera Segmentina, Hippeutis, and Gyraulus. Second intermediate hosts are freshwater plants. Definitive hosts are pigs, rabbits, and canids. Zoonotic in humans (Ma et al. 2017; Sah et al. 2019; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae on contaminated freshwater vegetation (Sah et al. 2019; Chai and Jung 2020).
Site in human host. Small intestine (Sah et al. 2019; Chai and Jung 2020).
●●●●●●●●● Philophthalmidae Looss, 1899
Genus Philophthalmus Looss, 1899
Philophthalmusgralli Matthis & Leger, 1910
Philophthalmusanatinus Sugimoto, 1928
Philophthalmusnyrocae Yamaguti, 1934
Geographic distribution. East and Southeast Asia, North America, South America (Nollen and Kanev 1995).
Natural hosts. Intermediate hosts are snails in the genus Melanoides. Definitive hosts are birds, primarily water birds and fowl. Zoonotic in humans (Nollen and Kanev 1995).
Route of infection. Ingestion of metacercariae in water or on submerged substrates (e.g., mollusk shells, plants); also direct exposure of eyes to free-swimming cercariae in water (Nollen and Kanev 1995).
Site in human host. Eyes (Nollen and Kanev 1995).
Philophthalmuspalpebrarum Looss, 1899
Geographic distribution. Middle East, North Africa (Nollen and Kanev 1995).
Natural hosts. Intermediate hosts are snails in the genus Melanoides. Definitive hosts are birds, primarily water birds and fowl. Zoonotic in humans (Nollen and Kanev 1995).
Route of infection. Ingestion of metacercariae in water or on submerged substrates (e.g., mollusk shells, plants); also direct exposure of eyes to free-swimming cercariae in water (Nollen and Kanev 1995).
Site in human host. Eyes (Nollen and Kanev 1995).
Philophthalmuslacrymosus Braun, 1902
Geographic distribution. Central and South America (Nollen and Kanev 1995).
Natural hosts. Intermediate hosts are snails in the genus Melanoides. Definitive hosts are birds, primarily water birds and fowl. Zoonotic in humans (Nollen and Kanev 1995).
Route of infection. Ingestion of metacercariae in water or on submerged substrates (e.g., mollusk shells, plants); also direct exposure of eyes to free-swimming cercariae in water (Nollen and Kanev 1995).
Site in human host. Eyes (Nollen and Kanev 1995).
●●●●●●●● Hemiurata Skrjabin & Guschanskaja, 1954
●●●●●●●●● Isoparorchiidae Travassos, 1922
Genus Isoparorchis Southwell, 1913
Leptolecithum Kobayashi, 1915
Isoparorchishypselobagri (Billet, 1898)
Geographic distribution. Central and Southeast Asia, Russia, Australia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Melanoides. Second intermediate hosts are catfish. Definitive hosts are predator fish. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●● Opisthorchiata La Rue, 1957
●●●●●●●●● Heterophyidae Leiper, 1909
Genus Acanthotrema Travassos, 1928
Acanthotremafelis Sohn et al., 2003
Geographic distribution. Korea (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are brackish water fish in the genus Acanthogobius. Definitive hosts are felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Apophallus Lühe, 1909
Apophallusdonicus (Skrjabin & Lindtrop, 1919)
Geographic distribution. North America (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Flumenicola. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores and lagomorphs. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish intermediate host (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Ascocotyle Looss, 1899
Ascocotylelonga Ransom, 1920
Geographic distribution. North America, Europe (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails in the genus Helecobia. Second intermediate hosts are brackish water fish in the genus Mugil. Definitive hosts are canids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Centrocestus Looss, 1899
Centrocestusarmatus (Tanabe, 1922)
Geographic distribution. Korea, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Semisulcospira. Second intermediate hosts are freshwater fish in the genus Zacco. Definitive hosts are wild and domestic canids and felids, rabbits, rats, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Centrocestuscuspidatus (Looss, 1896)
Geographic distribution. Southeast Asia, North Africa, Middle East (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Oncomelania. Second intermediate hosts are freshwater fish in the genus Gambusia. Definitive hosts are carnivores, rodents, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Centrocestusformosanus Nishigori, 1924
Centrocestuscaninus Leiper, 1913
Geographic distribution. Southeast Asia, Central and South America, North Africa, Middle East (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Stenomelania. Second intermediate hosts are freshwater fish, including Cyclocheilichthys and Puntius. Definitive hosts are wild and domestic canids, chickens, and ducks. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Centrocestuskurokawai (Kurowawa, 1935)
Geographic distribution. Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are unknown but presumed to be freshwater fish. Definitive hosts unknown; presumed zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate host (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Cryptocotyle Lühe, 1899
Cryptocotylelingua (Creplin, 1825)
Geographic distribution. North America, Europe, Russia, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails in the genus Littorina. Second intermediate hosts are brackish and freshwater fish in the genus Gobius. Definitive hosts are carnivores, rodents, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Haplorchis Looss, 1899
Haplorchispumilio (Looss, 1896)
Geographic distribution. Central and Southeast Asia, Australia, Middle East, North Africa, Central and South America (Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genus Melania. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected freshwater fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Haplorchistaichui (Nishigori, 1924)
Monorchotremamicrorchia Katsuta, 1932
Geographic distribution. Central and Southeast Asia, Hawaii, Middle East (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Melania and Melanoides. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected freshwater fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Haplorchisvanissimus Africa, 1938
Geographic distribution. Australia, Philippines (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are unknown but presumed to be freshwater fish. Definitive hosts are wild and domestic canids and felids and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Haplorchisyokogawai (Katsuta, 1932)
Geographic distribution. Central and Southeast Asia, Australia, Middle East, North Africa (Chai and Jung 2020).
Natural hosts. First intermediate hosts include several genera of freshwater snails. Second intermediate hosts are various freshwater fish. Definitive hosts are mammals, including cattle and carnivores. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected freshwater fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Heterophyes Cobbold, 1866
Heterophyesheterophyes (Siebold, 1853)
Heterophyesaegyptiaca Cobbold, 1866
Geographic distribution. Central and Southeast Asia, Japan, Middle East, North Africa (Chai and Jung 2020).
Natural hosts. First intermediate hosts are various freshwater snails. Second intermediate hosts are various freshwater and brackish water fish. Definitive hosts are carnivores. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Heterophyesnocens Onji & Nishio, 1916
Heterophyeskatsuradai Ozaki & Asada, 1926
Geographic distribution. Korea, Japan China (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Cerithidea. Second intermediate hosts are freshwater fish in the genus Acanthogobius. Definitive hosts are wild and domestic and felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Heterophyopsis Tubangui & Africa, 1938
Heterophyopsiscontinua (Onki & Nishio, 1916)
Geographic distribution. Korea, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores and birds. Zoonotic in humans(Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Metagonimus Katsurada, 1912
Metagonimuskatsuradai Izumi, 1935
Geographic distribution. Japan, Russia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Semisulcospira. Second intermediate hosts are freshwater fish in the genus Tanakia. Definitive hosts are carnivores. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Metagonimusminutus Katsuta, 1932
Geographic distribution. Taiwan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are brackish water fish in the genus Mugil. Definitive hosts are unknown; presumed zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Metagonimusmiyatai Saito et al., 1997
Geographic distribution. Korea, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Semisulcospira. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores, rodents, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Metagonimustakahashii Takahashi, 1929
Geographic distribution. Korea, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Semisulcospira and Koreanomelania. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Metagonimusyokogawai (Katsurada, 1912)
Geographic distribution. Central and Southeast Asia, Russia, Japan, Europe (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Semisulcospira. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores, rodents, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Procerovum Onji & Nishio, 1916
Procerovumcalderoni (Africa & Garcia, 1935)
Geographic distribution. Egypt, Southeast Asia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails in the genus Sermyla. Second intermediate hosts are freshwater fish in the genus Ophiocephalis. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Procerovumvarium Onji & Nishio, 1916
Geographic distribution. Korea, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails in the genus Melanoides. Second intermediate hosts are brackish water fish in the genus Mugil. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Pygidiopsis Looss, 1907
Pygidiopsisgenata Looss, 1907
Geographic distribution. North Africa, Middle East, Eastern Europe, Philippines (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Melanoides and Melanopsis. Second intermediate hosts are various freshwater fish. Definitive hosts are carnivores, rodents, shrews, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Pygidiopsissumma Onji & Nishio, 1916
Geographic distribution. Korea, Japan, Vietnam (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are brackish water fish in the genera Mugil and Acnathogonius. Definitive hosts are wild and domestic felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Stellantchasmus Onji & Nishio, 1916
Stellantchasmusfalcatus Onji & Nishio, 1916
Geographic distribution. Central and Southeast Asia, Japan, Middle East, Australia, Hawaii (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genera Stenomelania and Thiara. Second intermediate hosts are mullets. Definitive hosts are wild and domestic canids and felids, rabbits, rats, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Stictodora Looss, 1899
Stictodorafuscata (Onji & Nishio, 1916)
Geographic distribution. Korea, Japan, Kuwait (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are brackish water fish in the genera Acanthogobius and Pseudorasbora. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Stictodoralari Yamaguti, 1939
Geographic distribution. Southeast Asia, Japan, Russia, Australia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails, including the genus Velacumantus. Second intermediate hosts are various brackish water fish. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected fish (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Opisthorchiidae Looss, 1899
Genus Amphimerus Barker, 1911
Geographic distribution. North, Central, and South America (Calvopiña et al. 2011, 2015).
Natural hosts. Intermediate hosts are various freshwater snails. Second intermediate hosts are freshwater fish. Natural hosts are a variety of mammals, birds, and reptiles, including domestic dogs and cats. Zoonotic in humans (Calvopiña et al. 2011, 2015).
Route of infection. Ingestion of metacercariae in infected fish (Calvopiña et al. 2011).
Site in human host. Liver (Calvopiña et al. 2011).
Notes. The natural hosts and species identification have not been confirmed from human isolates, most of which have been documented in Ecuador.
Genus Clonorchis Looss, 1907
Clonorchissinensis (Cobbold, 1875)
Geographic distribution. East Asia; hot spots of endemicity for human disease include Korea, China, Taiwan, and Vietnam (Qian et al. 2012).
Natural hosts. First intermediate hosts are various genera of freshwater snails. Second intermediate host are a variety of freshwater fish, primarily cyprinids. Definitive hosts are fish-eating mammals, including wild and domestic canids and felids, mustelids, and pigs. Zoonotic in humans (Qian et al. 2012).
Route of infection. Ingestion of metacercariae in infected fish (Qian et al. 2012).
Site in human host. Biliary ducts (Qian et al. 2012).
Genus Metorchis Looss, 1899
Metorchisbilis (Braun, 1790)
Distomaalbidus Braun, 1893
Distomacrassiusculus Rudolphi, 1809
Geographic distribution. Central and Eastern Europe, Russia (Mordvinov et al. 2012).
Natural hosts. First intermediate hosts include snails of the genus Bithynia. Second intermediate hosts are typically cyprinid fishes (e.g., carps, minnows). Natural definitive hosts are various fish-eating mammals and birds. Zoonotic in humans (Mordvinov et al. 2012).
Route of infection. Ingestion of metacercariae in infected fish (Mordvinov et al. 2012).
Site in human host. Biliary ducts (Mordvinov et al. 2012).
Metorchisconjunctus (Cobbold, 1860)
Geographic distribution. Northern North America (Behr et al. 1998).
Natural hosts. First intermediate hosts are freshwater snails in the genus Amnicola. Second intermediate hosts are freshwater fish, primarily members of the genus Catostomus. Definitive hosts are carnivores. Zoonotic in humans (Behr et al. 1998).
Route of infection. Ingestion of metacercariae in infected fish (MacLean et al. 1996; Behr et al. 1998).
Site in human host. Biliary ducts (MacLean et al. 1996; Behr et al. 1998).
Metorchisorientalis Tanabe, 1921
Geographic distribution. East Asia (Na et al. 2016).
Natural hosts. First intermediate hosts include snails of the genera Bithynia and Parafossarulus. Second intermediate hosts are typically cyprinid fishes (e.g., carps, minnows). Natural definitive hosts are various fish-eating mammals and birds. Zoonotic in humans (Na et al. 2016).
Route of infection. Ingestion of metacercariae in infected fish (Na et al. 2016).
Site in human host. Biliary ducts (Na et al. 2016).
Metorchistaiwanensis Morishita & Tsuchimochi, 1952
Geographic distribution. East Asia (Zhan et al. 2017).
Natural hosts. First intermediate hosts include snails of the genus Bithynia. Second intermediate hosts are typically cyprinid fishes (e.g., carps, minnows). Natural definitive hosts are various fish-eating mammals and birds. Zoonotic in humans (Zhan et al. 2017).
Route of infection. Ingestion of metacercariae in infected fish (Zhan et al. 2017).
Site in human host. Biliary ducts (Zhan et al. 2017).
Genus Opisthorchis Blanchard, 1895
Opisthorchisfelineus (Rivolta, 1884)
Geographic distribution. Eastern Europe, Russia, Central Asia (Pakharukova and Mordvinov 2016).
Natural hosts. First intermediate hosts are freshwater snails in the genus Bithynia. Second intermediate hosts are various freshwater fish. Definitive hosts are mammals, primarily carnivores. Zoonotic in humans (Pakharukova and Mordvinov 2016).
Route of infection. Ingestion of metacercariae in infected fish (Pakharukova and Mordvinov 2016).
Site in human host. Biliary ducts (Pakharukova and Mordvinov 2016).
Opisthorchisviverrini (Poirier, 1886)
Geographic distribution. Southeast Asia, with high prevalence of human infection in Thailand, Laos, Vietnam, and Cambodia (Kaewpitoon et al. 2008; Suwannatrai et al. 2018).
Natural hosts. First intermediate hosts are freshwater snails in the genus Bithynia. Second intermediate hosts are various freshwater fish. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Kaewpitoon et al. 2008; Suwannatrai et al. 2018).
Route of infection. Ingestion of metacercariae in infected fish (Kaewpitoon et al. 2008).
Site in human host. Biliary ducts (Kaewpitoon et al. 2008).
Genus Pseudamphistomum Lühe, 1908
Pseudamphistomumtruncatum (Rudolphi, 1819)
Geographic distribution. Europe, Asia (Neimanis et al. 2016).
Natural hosts. First intermediate hosts are freshwater and brackish snails. Second intermediate host are freshwater, brackish, and marine fish, primarily cyprinids. Definitive hosts are carnivores, including cats, pinnipeds, and mustelids. Zoonotic in humans (Neimanis et al. 2016).
Route of infection. Ingestion of metacercariae in infected fish (Neimanis et al. 2016).
Site in human host. Biliary ducts (Neimanis et al. 2016).
●●●●●●●● Pronocephalata Olson et al., 2003
●●●●●●●●● Paramphistomidae Fischoeder, 1901
Genus Fischoederius Stiles & Goldberger, 1910
Fischoederiuselongatus (Poirier, 1883)
Geographic distribution. Europe, Russia, Central and Southeast Asia, Japan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Lymnaea. Second intermediate hosts are freshwater plants. Definitive hosts are cattle, deer, goats, and sheep. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae on contaminated aquatic vegetation (Chai and Jung 2020)
Site in human host. Small intestine (Chai and Jung 2020).
Genus Gastrodiscoides Leiper, 1913
Gastrodiscoideshominis (Lewis & McConnell, 1876)
Geographic distribution. Europe, Central and Southeast Asia(Mas-Coma 2006; Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Helicorbis. Second intermediate hosts are freshwater plants, amphibians, and crayfish. Definitive hosts are pigs and humans (Mas-Coma 2006; Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Mas-Coma 2006; Chai and Jung 2020).
Site in human host. Small intestine (Mas-Coma 2006; Chai and Jung 2020).
Genus Watsonius Stiles & Goldberger, 1910
Watsoniuswatsoni (Conyngham, 1904)
Geographic distribution. Sub-Saharan Africa, Vietnam (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Physa. Second intermediate hosts are presumed to be freshwater vegetation. Definitive hosts are non-human primates. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae on contaminated aquatic vegetation (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●● Xiphidiata Olson et al., 2003
●●●●●●●●● Dicrocoeliidae Looss, 1899
Genus Dicrocoelium Dujardin, 1845
Dicrocoeliumdendriticum (Rudolphi, 1819)
Dicrocoeliumlanceolatum Stiles & Hassall, 1898
Geographic distribution. North America, Africa, Asia, Europe, Middle East (Cengiz et al. 2010).
Natural hosts. First intermediate hosts are various genera of terrestrial snails. Second intermediate hosts are ants (primarily genus Formica). Definitive hosts are ungulates, including cattle, sheep, and goats. Zoonotic in humans (Cengiz et al. 2010).
Route of infection. Ingestion of metacercariae in infected ants (Cengiz et al. 2010).
Site in human host. Bile ducts, gall bladder (Cengiz et al. 2010).
Dicrocoeliumhospes Looss, 1907
Geographic distribution. West Africa (Odei 1966).
Natural hosts. First intermediate hosts are snails in the genera Achatina and Limicolaria. Second intermediate hosts are ants in the genera Dorylus and Crematogaster. Definitive hosts are ungulates, including cattle and sheep. Zoonotic in humans (Odei 1966).
Route of infection. Ingestion of infected intermediate hosts (Odei 1966).
Site in human host. Bile ducts (Odei 1966)
Notes. It is uncertain whether D.hospes causes true infection in humans. Most reported cases of the finding of eggs in stool are believed to be spurious after the consumption of infected beef liver (Wolfe 2007). The two cases from Ghana believed to be true infections are in children who denied eating beef liver (Odei 1966). True infection should be confirmed by the examination of follow-up stool specimens (Wolfe 2007).
●●●●●●●●● Lecithodendriidae Lühe, 1901
Genus Caprimolgorchis Jha, 1943
Caprimolgorchismolenkampi Lie Kian Joe, 1961
Geographic distribution. Southeast Asia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown, but hypothesized to be freshwater snails in the genera Bithynia or Zebrina. Second intermediate hosts are dragonflies and damselflies. Definitive hosts are rodents and bats. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of infected insects (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Microphalidae Ward, 1901
Genus Gynaecotyla Yamaguti, 1939
Gynaecotylasquatarolae (Yamaguti, 1934)
Geographic distribution. Japan, South Korea, Taiwan (Chai and Jung 2020).
Natural hosts. First intermediate hosts are brackish water snails in the genus Batillaria. Second intermediate hosts are brackish water crabs in the genus Macrophthalmus. Definitive hosts are shorebirds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected crabs (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Genus Microphallus Ward, 1901
Microphallusbrevicaeca (Africa & Garcia, 1935)
Geographic distribution. Papua New Guinea, Philippines (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are brackish water crustaceans in the genera Carcinus and Macrobrachium. Definitive hosts are birds and mammals, especially non-human primates. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected crustaceans (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Phaeneropsolidae Mehra, 1935
Genus Phaneropsolus Looss, 1899
Phaneropsolusbonnei Lie Kian Joe, 1951
Geographic distribution. Central and Southeast Asia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown, but hypothesized to be freshwater snails in the genus Bithynia. Second intermediate hosts are dragonflies and damselflies. Definitive hosts are non-human primates. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of infected insects (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Phaneropsolusspinicirrus Kaewkes et al., 1991
Geographic distribution. Thailand (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are unknown, but presumed to be dragonflies and damselflies. Definitive hosts are unknown; presumed zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of infected intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●●● Plagiorchiidae Lühe, 1901
Genus Plagiorchis Lühe, 1899
Plagiorchisjavensis Sandground, 1940
Geographic distribution. Indonesia (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts include snails, insects, and possibly fish. Definitive hosts are birds and bats. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Plagiorchismuris (Tanabe, 1922)
Geographic distribution. Europe, Central and Southeast Asia, Japan, North and Central America (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Lymnaea. Second intermediate hosts are freshwater insects, crustaceans, and fish. Definitive hosts are canids, felids, raccoons, rodents, bats, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Plagiorchisphilippinensis Africa & Garcia, 1937
Geographic distribution. Philippines (Chai and Jung 2020).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are presumed to be aquatic insects. Definitive hosts rodents and possibly birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Plagiorchisvespertilionis (Müller, 1784)
Geographic distribution. Europe, North Africa, Central and Southeast Asia, Japan, Madagascar, North America (Chai and Jung 2020).
Natural hosts. First intermediate hosts are freshwater snails in the genus Lymnaea. Second intermediate hosts are freshwater insects. Definitive hosts are rodents and bats. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected insect intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
●●●●●●●● Troglotremata Schell, 1890
●●●●●●●●● Nanophyetidae Dollfus, 1939
Genus Nanophyetus Chapin, 1928
Nanophyetussalmincola (Chapin, 1926)
Geographic distribution. Northern North America (Chai and Jung 2020).
Natural hosts. First intermediate hosts are snails in the genus Oxytrema. Second intermediate hosts are several general of freshwater fish, especially salmonids. Definitive hosts canids, felids, raccoons, and birds. Zoonotic in humans (Chai and Jung 2020).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Chai and Jung 2020).
Site in human host. Small intestine (Chai and Jung 2020).
Nanophyetusschikhobalowi Skrjabin & Podiapolskaia, 1931
Geographic distribution. Northern Eurasia (Voronova et al. 2017; Voronova and Chelomina 2018).
Natural hosts. First intermediate hosts are snails in the genus Oxytrema. Second intermediate hosts are several general of freshwater fish, especially salmonids. Definitive hosts canids, felids, raccoons, and birds. Zoonotic in humans (Voronova et al. 2017; Voronova and Chelomina 2018).
Route of infection. Ingestion of metacercariae in infected intermediate hosts (Voronova et al. 2017; Voronova and Chelomina 2018).
Site in human host. Small intestine (Voronova et al. 2017; Voronova and Chelomina 2018).
●●●●●●●●● Paragonimidae Dollfus, 1939
Genus Paragonimus Braun, 1899
Paragonimusafricanus Volker & Vogel, 1965
Geographic distribution. West Africa (Blair et al. 1999; Cumberlidge et al. 2018).
Natural hosts. First intermediate hosts are presumed to be freshwater or brackish snails, but the specific species have yet to be identified. Second intermediate hosts are freshwater crabs in the family Potamidae. Definitive hosts are carnivores and non-human primates. Zoonotic in humans (Blair et al. 1999; Cumberlidge et al. 2018).
Route of infection. Ingestion of metacercariae in infected intermediate or paratenic hosts (Blair et al. 1999; Cumberlidge et al. 2018).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999; Cumberlidge et al. 2018).
Paragonimusheterotremus Chen & Hsia, 1964
Paragonimustuanshansis Chung et al., 1964
Paragonimuspseudoheterotremus Waikagul et al., 2007
Geographic distribution. Southeast Asia (Yoshida et al. 2019).
Natural hosts. First intermediate hosts are freshwater snails in the superfamily Rissooidea. Second intermediate hosts are freshwater crabs in the families Potamidae and Parathelphusidae. Definitive hosts are carnivores and non-human primates. Wild boar, rodents, and deer can serve as paratenic hosts. Zoonotic in humans (Yoshida et al. 2019).
Route of infection. Ingestion of metacercariae in infected intermediate or paratenic hosts (Yoshida et al. 2019).
Site in human host. Lungs, possibly ectopic infection at other sites (Yoshida et al. 2019).
Notes.Paragonimusheterotremus is often referred to as a species complex; the status of many members as distinct and valid species is an area of ongoing investigation.
Paragonimuskellicotti Ward, 1908
Geographic distribution. Eastern and Midwestern North America (Procop 2009).
Natural hosts. First intermediate hosts are freshwater snails in the family Pomatiopsidae. Second intermediate hosts are freshwater crayfish, primarily of the family Astacidae. Definitive hosts are carnivores and marsupials. Zoonotic in humans (Procop 2009).
Route of infection. Ingestion of metacercariae in infected intermediate and paratenic hosts (Procop 2009).
Site in human host. Lungs, possibly ectopic infection at other sites (Procop 2009).
Paragonimusmexicanus Miyazaki & Ishii, 1968
Paragonimusperuvianus Miyazaki et al., 1969
Paragonimusecuadorensis Voekler & Arzube, 1979
Geographic distribution. Central and South America (Blair et al. 1999).
Natural hosts. First intermediate hosts are freshwater and brackish snails in the families Hydrobiidae and Pomatiopsidae. Second intermediate hosts are freshwater crabs in the families Pseudothelphusidae and Trichodactylidae. Definitive hosts are carnivores and marsupials. Zoonotic in humans (Blair et al. 1999).
Route of infection. Ingestion of metacercariae in infected crustaceans (Blair et al. 1999).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999).
Paragonimusohirai Miyazaki, 1939
Paragonimusiloktsuensis Chen, 1940
Paragonimussadoensis Miyazaki et al., 1968
Geographic distribution. East Asia (Blair et al. 1999; Yoshida et al. 2019).
Natural hosts. First intermediate hosts are freshwater and brackish snails in the families Assimineidae and Pomatiopsidae. Second intermediate hosts are freshwater crabs in the family Potamidae and brackish crabs in the family Grapsidae. Definitive hosts are carnivores. Zoonotic in humans (Blair et al. 1999; Yoshida et al. 2019).
Route of infection. Ingestion of metacercariae in infected intermediate or paratenic hosts (Blair et al. 1999; Yoshida et al. 2019).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999; Yoshida et al. 2019).
Notes.Paragonimusohirai is often referred to as a species complex; the status of many members as distinct and valid species is an area of ongoing investigation.
Paragonimusskrjabini Chen, 1959
Paragonimusmiyazakii Kamo et al., 1961
Paragonimusszechuanensis Chung & Tsao, 1962
Paragonimushueitungensis Chung et al., 1975
Paragonimusveocularis Chen & Li, 1979
Geographic distribution. East and Southeast Asia, Indian subcontinent (Blair et al. 1999; Yoshida et al. 2019).
Natural hosts. First intermediate hosts are freshwater and brackish snails in the superfamily Rissooidea. Second intermediate hosts are freshwater crabs in the families Potamidae and Parathelphusidae. Definitive hosts are carnivores. Wild boar, rodents, and deer may serve as paratenic hosts. Zoonotic in humans (Blair et al. 1999; Yoshida et al. 2019).
Route of infection. Ingestion of metacercariae in infected intermediate and paratenic hosts (Blair et al. 1999; Yoshida et al. 2019).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999; Yoshida et al. 2019).
Notes.Paragonimusskrjabini is often referred to as a species complex; the status of many members as distinct and valid species is an area of ongoing investigation.
Paragonimusuterobilateralis Volker & Vogel, 1965
Geographic distribution. West Africa (Blair et al. 1999; Cumberlidge et al. 2018).
Natural hosts. First intermediate hosts are presumed to be freshwater or brackish snails, but the specific species have yet to be identified. Second intermediate hosts are freshwater crabs in the family Potamidae. Definitive hosts are carnivores. Zoonotic in humans (Blair et al. 1999; Cumberlidge et al. 2018).
Route of infection. Ingestion of metacercariae in infected intermediate or paratenic hosts (Blair et al. 1999; Cumberlidge et al. 2018).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999; Cumberlidge et al. 2018).
Paragonimuswestermani (Kerbert, 1878)
Distomapulmonalis Baelz, 1880
Distomaringeri Cobbold, 1880
Paragonimusedwardsi Gulati, 1926
Paragonimusmacacae Sandosham, 1953
Paragonimusasymmetricus Chen, 1977
Paragonimusfilipinus Miyazaki, 1978
Paragonimusphilippinensis Ito et al., 1978
Geographic distribution. East and Southeast Asia, Indian subcontinent, Siberia (Blair et al. 1999; YBlair 2019; oshida et al. 2019).
Natural hosts. First intermediate hosts are freshwater and brackish snails in the superfamily Cerithioidea. Second intermediate hosts are freshwater crabs in the families Potamidae and Parathelphusidae. Definitive hosts are carnivores and non-human primates. Wild boar, rodents, and deer may serve as paratenic hosts. Zoonotic in humans (Blair et al. 1999; Blair 2019; Yoshida et al. 2019).
Route of infection. Ingestion of metacercariae in infected intermediate or paratenic hosts (Blair et al. 1999; Blair 2019; Yoshida et al. 2019).
Site in human host. Lungs, possibly ectopic infection at other sites (Blair et al. 1999; Blair 2019; Yoshida et al. 2019).
Notes.Paragonimuswestermani is often referred to as a species complex; the status of many members as distinct and valid species is an area of ongoing investigation.
●●●●●●●●● Orchipedidae Skrjabin, 1913
Achillurbainiidae Dollfus, 1939
Genus Achillurbainia Dolffus, 1939
Poikilorchis Fain & Vandepitte, 1957
Achillurbainiacongolensis (Fain & Vandepitte, 1957)
Geographic distribution. Sub-Saharan Africa (Fain and Vandepitte 1957; Nieuwenhuyse and Gatti 1968).
Natural hosts. Unknown; presumed zoonotic in humans (Fain and Vandepitte 1957; Nieuwenhuyse and Gatti 1968).
Route of infection. Unknown.
Site in human host. Subcutaneous cysts (usually near the ear), mastoid, middle ear (Fain and Vandepitte 1957; Nieuwenhuyse and Gatti 1968).
Achillurbainianouveli Dolffus, 1939
Geographic distribution. Southeast Asia (human case from China) (Kannangara 1971).
Natural hosts. First intermediate hosts are unknown. Second intermediate hosts are freshwater crabs (Paratelphusa). Definitive hosts are leopards. Zoonotic in humans (Kannangara 1971; Kwo and Lim 1968).
Route of infection. Unknown, presumed ingestion of metacercariae in undercooked crabs (Kannangara 1971).
Site in human host. Subcutaneous cysts (near the ear) (Kannangara 1971).
Achillurbainiarecondita Travassos, 1942
Geographic distribution. Central and South America (Beaver et al. 1977).
Natural hosts. Intermediate hosts unknown. Definitive hosts are opossums (Didelphismarsupialis). Zoonotic in humans (Beaver et al. 1977).
Route of infection. Unknown.
Site in human host. Peritoneal cavity (Beaver et al. 1977).
●●●● Ecdysozoa Anguinaldo et al., 1997
●●●●● Panarthropoda Nielsen, 1995
●●●●●● Arthropoda von Siebold, 1848
●●●●●●● Chelicerata Heymons, 1901
●●●●●●●● Euchelicerata Weygoldt & Paulus, 1979
●●●●●●●●● Arachnida Lamarck, 1801
●●●●●●●●●● Acari Leach, 1817
●●●●●●●●●●● Acariformes Zakhvatkin, 1952
●●●●●●●●●●●● Sarcoptiformes Reuter, 1909
●●●●●●●●●●●●● Astigmatina Canestrini, 1891
●●●●●●●●●●●●●● Acaridia Latreille, 1802
●●●●●●●●●●●●●●● Histiostomatidae Berlese, 1897
Histiostomatidae, incertae sedis
Geographic distribution. Unknown (single human case from Saudi Arabia) (Al-Arfaj et al. 2007).
Natural hosts. Unknown
Route of infection. Unknown, presumed exposure to fresh water (Al-Arfaj et al. 2007).
Site in human host. Ear (Al-Arfaj et al. 2007).
Vectored pathogens. None
Notes. Histostomatid mites were isolated from the ear of a Saudi man who travelled to the United States in 2007. The mites were reported as being an undescribed species of Histiostomatidae close to Loxantoetus (Al-Arfaj et al. 2007). At the time of this writing, the species had still not been described (Gary Mullen, pers. comm. 2020).
●●●●●●●●●●●●●●● Acaridae Latreille, 1802
Genus Sancassania Oudemans, 1916
Sancassaniaberlesei (Michael, 1903)
Geographic distribution. Worldwide (Timms et al. 1981).
Natural hosts. None; cause incidental infestations in humans (Timms et al. 1981).
Route of infection. Contamination from the environment.
Site in human host. Mastoid cavity, ear (Cho et al. 1999; Paleri and Ruckley 2001).
Vectored pathogens. None.
Genus Cosmoglyphus Oudemans, 1932
Geographic distribution. Worldwide (Lombert et al. 1982).
Natural hosts. None; cause incidental infestations in humans (Lombert et al. 1982).
Route of infection. Contamination from the environment.
Site in human host. Ear (Pal et al. 2018).
Vectored pathogens. None.
Notes. Isolates of Cosmoglyphus from human clinical specimens have not been characterized at the species level.
Genus Rhizoglyphus Claparédè, 1869
Geographic distribution. Worldwide (Fan and Zhang 2004).
Natural hosts. None; cause incidental infestations in humans (Fan and Zhang 2004).
Route of infection. Contamination from the environment
Site in human host. Ear (Kiakojouri et al. 2018).
Vectored pathogens. None
Notes.Rhizoglyphus from human clinical specimens have not been characterized at the species level.
●●●●●●●●●●●●●●● Chorotoglyphidae Berlese, 1897
Genus Chorotoglyphus Berlese, 1884
Chorotoglyphusarcuatus (Troupeau, 1879)
Geographic distribution. Worldwide (Abi-Akl 2017).
Natural hosts. None; cause incidental infections in humans (Abi-Akl 2017).
Route of infection. Contamination from the environment.
Site in human host. Ear (Abi-Akl 2017).
Vectored pathogens. None.
Notes. The species-level identification of C.arcuatus isolated from the ear of a man in Lebanon was considered tentative based on morphologic characteristics (Abi-Akl 2017).
●●●●●●●●●●●●●● Psoroptidia Yunker, 1955
●●●●●●●●●●●●●●● Pyroglyphidae Cunliffe, 1958
Genus Dermatophagoides Bogdanov, 1864
Dermatophagoidesfarinae Hughes, 1961
Geographic distribution. Worldwide, more prevalent in North America (Hart and Fain 1988).
Natural hosts. None; cause incidental infections in humans (Hart and Fain 1988).
Route of infection. Contamination from the environment.
Site in human host. Ear (Liao and Chang 2012).
Vectored pathogens. None.
Notes. The finding of D.farinae in stool (Kapoor et al. 2019) probably represents spurious passage after the incidental ingestion of mites in contaminated foodstuffs or contamination of the stool specimen. Dust mites in urine also probably represent contamination of the urine specimens (Dini and Frean 2005; Siebers 2014).
●●●●●●●●●●●●●●● Psoroptidae Canestrini, 1892
Genus Otodectes Canestrini, 1894
Otodectescynotis (Hering, 1838)
Geographic distribution. Worldwide (Sweatman 1958).
Natural hosts. Carnivores, primarily dogs, cats, and ferrets. Zoonotic in humans (Sweatman 1958).
Route of infection. Contamination from the environment.
Site in human host. Ear (Van de Heyning and Thienpont 1977).
Vectored pathogens. None.
Genus Psoroptes Gervais, 1841
Psoroptesovis (Hering, 1838)
Geographic distribution. Worldwide (Mazyad et al. 2001; Ken et al. 2014).
Natural hosts. Mammals, primarily sheep, but also horses, cattle, goats. Zoonotic on humans (Mazyad et al. 2001; Ken et al. 2014).
Route of infection. Contact with infected animal hosts (Mazyad et al. 2001; Ken et al. 2014).
Site in human host. Skin (Mazyad et al. 2001; Ken et al. 2014).
Vectored pathogens. None.
●●●●●●●●●●●●●●● Sarcoptidae Murray, 1877
Genus Notoedres Railliet, 1893
Notoedrescati (Hering, 1838)
Geographic distribution. Worldwide (Sivajothi et al. 2015).
Natural hosts. Cats and other felids. Zoonotic on humans (Sivajothi et al. 2015).
Route of infection. Contact with infected felid hosts (Chakrabarti 1986).
Site in human host. Skin (Chakrabarti 1986; Beck and Pfister 2006).
Vectored pathogens. None.
Genus Sarcoptes Latreille, 1802
Sarcoptesscabiei (Linnaeus, 1758)
Geographic distribution. Worldwide (Arlian and Morgan 2017; Chandler and Fuller 2019).
Natural hosts. Humans (other animals have their own varieties and subspecies) (Arlian and Morgan 2017; Chandler and Fuller 2019).
Route of infection. Direct person-to-person contact or contaminated fomites (Arlian and Morgan 2017; Chandler and Fuller 2019).
Site in human host. Skin (Arlian and Morgan 2017; Chandler and Fuller 2019).
Vectored pathogens. None.
Genus Trixacarus Sellnick, 1944
Trixacaruscaviae Fain et al., 1972
Geographic distribution. Worldwide (Dorrestein and Van Bronswijk 1979).
Natural hosts. Domestic Guinea pigs. Zoonotic on humans (Dorrestein and Van Bronswijk 1979).
Route of infection. Contact with infected Guinea pigs (Dorrestein and Van Bronswijk 1979).
Site in human host. Skin (Dorrestein and Van Bronswijk 1979).
Vectored pathogens. None.
●●●●●●●●●●●● Trombidiformes Reuter, 1909
●●●●●●●●●●●●● Prostigmata Kramer, 1877
●●●●●●●●●●●●●● Trombidoidea Leach, 1815
●●●●●●●●●●●●●●● Trombiculidae Ewing, 1929
Genus Eutrombicula Ewing, 1938
Eutrombiculaalfreddugesi (Oudemans, 1910)
Geographic distribution. Western Hemisphere (Diaz 2009).
Natural hosts. Mammals and birds. Zoonotic on humans as incidental hosts (Diaz 2009).
Route of infection. Exposure to larvae in the environment (Diaz 2009).
Site in human host. Skin (Diaz 2009).
Vectored pathogens. None.
Eutrombiculasarcia (Womersley, 1944)
Geographic distribution. Asia, Australia (Diaz 2009).
Natural hosts. Mammals and birds. Zoonotic on humans as incidental hosts (Diaz 2009).
Route of infection. Exposure to larvae in the environment (Diaz 2009).
Site in human host. Skin.
Vectored pathogens. None.
Genus Leptotrombidium Nagayo et al., 1916
Leptotrombidiumakamushi (Brumpt, 1910)
Geographic distribution. Japan (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019).
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin.
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Leptotrombidiumarenicola (Traub, 1960)
Geographic distribution. Malaysia (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019).
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin.
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Leptotrombidiumdeliense (Walch, 1922)
Geographic distribution. Southeast Asia, Japan, Philippines, Australia, Pacific Islands (Lv et al. 2018).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Lv et al. 2018).
Route of infection. Exposure to larvae in the environment (Lv et al. 2018).
Site in human host. Skin.
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Lv et al. 2018).
Leptotrombidiumfletcheri (Womersley & Heaslip, 1943)
Geographic distribution. Malaysia (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019)
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin.
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Leptotrombidiumpallidum (Nagayo et al., 1919)
Geographic distribution. Japan (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019).
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Leptotrombidiumpavlovskyi (Schluger, 1948)
Geographic distribution. Eastern Russia (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019).
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Leptotrombidiumscutellaris (Nagayo et al., 1921)
Geographic distribution. Japan (Diaz 2009; Elliott et al. 2019).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Diaz 2009; Elliott et al. 2019).
Route of infection. Exposure to larvae in the environment (Diaz 2009; Elliott et al. 2019).
Site in human host. Skin
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Diaz 2009; Elliott et al. 2019).
Genus Neotrombicula Hirst, 1925
Neotrombiculaautumnalis (Shaw, 1790)
Geographic distribution. Europe (Schöler et al. 2006).
Natural hosts. Mammals and birds. Zoonotic on humans as incidental hosts (Schöler et al. 2006).
Route of infection. Exposure to larvae in the environment (Diaz 2009).
Site in human host. Skin.
Vectored pathogens. None.
Genus Schoengastiella Hirst, 1915
Schoengastiellaligula Radford, 1946
Geographic distribution. South Asia (Tilak et al. 2011; Luce-Fedrow et al. 2018).
Natural hosts. Rodents and insectivores. Zoonotic on humans as incidental hosts (Tilak et al. 2011; Luce-Fedrow et al. 2018).
Route of infection. Exposure to larvae in the environment (Tilak et al. 2011; Luce-Fedrow et al. 2018).
Site in human host. Skin
Vectored pathogens.Orientiatsutsugamushi (Oriental scrub typhus) (Tilak et al. 2011; Luce-Fedrow et al. 2018).
●●●●●●●●●●●●●● Cheyletoidea Leach, 1815
●●●●●●●●●●●●●●● Cheyletidae Leach, 1815
Genus Cheyletiella Canestrini, 1886
Cheyletiellablakei Smikey, 1970
Geographic distribution. Worldwide (Keh and Lane 1987; Wagner and Stallmeister 2000).
Natural hosts. Cats. Zoonotic on humans as incidental hosts (Keh and Lane 1987; Wagner and Stallmeister 2000).
Route of infection. Exposure to infected cats (Keh and Lane 1987; Wagner and Stallmeister 2000).
Site in human host. Skin (Keh and Lane 1987; Wagner and Stallmeister 2000).
Vectored pathogens. None.
Cheyletiellaparasitovorax Mégnin, 1877
Geographic distribution. Worldwide (Harcourt-Brown 2002).
Natural hosts. Rabbits. Zoonotic on humans as incidental hosts (Harcourt-Brown 2002).
Route of infection. Exposure to infected rabbits (Milman and Dik 2017).
Site in human host. Skin (Milman and Dik 2017).
Vectored pathogens. None.
Cheyletiellayasguri Smiley, 1965
Geographic distribution. Worldwide (Foxx and Ewing 1969).
Natural hosts. Dogs. Zoonotic on humans as incidental hosts (Foxx and Ewing 1969).
Route of infection. Exposure to infected dogs (Powell et al. 1977).
Site in human host. Skin (Powell et al. 1977).
Vectored pathogens. None.
●●●●●●●●●●●●●●● Demodecidae Nicolet, 1855
Genus Demodex Owen, 1843
Demodexbrevis Akbulatova, 1963
Geographic distribution. Worldwide (Rather and Hassan 2014).
Natural hosts. Humans (Rather and Hassan 2014).
Route of infection. Direct person-to-person contact (Rather and Hassan 2014).
Site in human host. Skin, sebaceous glands (Rather and Hassan 2014).
Vectored pathogens. None.
Demodexfolliculorum Simon, 1842
Geographic distribution. Worldwide (Rather and Hassan 2014).
Natural hosts. Humans (Rather and Hassan 2014).
Route of infection. Direct person-to-person contact (Rather and Hassan 2014).
Site in human host. Skin, hair follicles (Rather and Hassan 2014).
Vectored pathogens. None.
●●●●●●●●●●●●●● Tarsonemoidea Kramer, 1877
●●●●●●●●●●●●●●● Pyemotidae Oudemans, 1937
Genus Pyemotes Amerling, 1861
Pyemotesherfsi (Oudemans, 1936)
Geographic distribution. North America, Europe, North Africa, India, Australia (Broce et al. 2006).
Natural hosts. Insects. Zoonotic on humans as incidental hosts (Broce et al. 2006).
Route of infection. Environmental exposure (Broce et al. 2006).
Site in human host. Skin (Broce et al. 2006).
Vectored pathogens. None.
Pyemotestritici (LaGrèze-Fossat & Montagné, 1851)
Geographic distribution. Worldwide (Yu et al. 2010).
Natural hosts. Insects. Zoonotic on humans as incidental hosts (Yu et al. 2010).
Route of infection. Environmental exposure (Rosen et al. 2002).
Site in human host. Skin (Rosen et al. 2002).
Vectored pathogens. None.
Pyemotesventricosus (Newport, 1850)
Geographic distribution. Southern Europe (Moser 1975).
Natural hosts. Insects. Zoonotic on humans as incidental hosts (Moser 1975).
Route of infection. Environmental exposure (Diaz 2009).
Site in human host. Skin (Diaz 2009).
Vectored pathogens. None.
●●●●●●●●●●● Parasitiformes Leach, 1815
●●●●●●●●●●●● Ixodoidea Leach, 1815
●●●●●●●●●●●●● Ixodidae Koch, 1844
Genus Amblyomma Koch, 1844
Amblyommaamericanum (Linnaeus, 1758)
Ixodesunipunctata Packard, 1869
Geographic distribution. Eastern North America (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Many birds and mammals, including humans (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Ehrlichiachaffeensis (human monocytic ehrlichiosis), E.ewingii (human granulocytic ehrlichiosis), Francisellatularensis (tularemia), Heartland virus, Bourbon virus; also implicated in alpha-gal syndrome and Southern Tick-Associated Rash Illness (STARI) (Madison-Antenucci et al. 2020).
Amblyommaaureolatum (Pallas, 1772)
Amblyommastriatum Koch, 1844
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including carnivores and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain Spotted Fever) (Szabó et al. 2013).
Amblyommababirussae Schülze, 1933
Geographic distribution. Indonesia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including pigs, bovids, deer, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommabrasiliense Aragão, 1908
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Several mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommabreviscutatum Neumann, 1899
Amblyommacyprium Koch & Neumann, 1899
Amblyommacypriumaeratipes Schülze, 1932
Geographic distribution. Southeast Asia, Australia, Pacific Islands (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents and small birds. Adults are primarily on mammals, including bovids, deer, pigs, horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommacajennense (Fabricius, 1787)
Geographic distribution. Southern United States, Central and South America, Caribbean (Cooley 1944; Martins et al. 2016; Guglielmone and Robbins 2018).
Natural hosts. Many mammals, including humans, and birds (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommacalcartum Neumann, 1899
Geographic distribution. Central and South America, Caribbean (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily anteaters; also birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaclypeolatum Neumann, 1899
Geographic distribution. India, Sri Lanka, Myanmar (Liyanaarachchi et al. 2015).
Natural hosts. Reptiles. Zoonotic on humans (Liyanaarachchi et al. 2015; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommacoelebs Neumann, 1899
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommacohaerens Dönitz, 1909
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, but also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommacordiferum Neumann, 1899
Geographic distribution. Southeast Asia (Audy 1960).
Natural hosts. Immature stages are primarily on rodents. Adults are on reptiles and ungulates. Zoonotic on humans (Audy 1960).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Notes. The single record of A.cordiferum from a human in Malaysia (Audy 1960) is considered a tentative identification (Guglielmone and Robbins 2018).
Amblyommadissimile Koch, 1844
Geographic distribution. North, Central, and South America and Caribbean (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Primarily reptiles and amphibians, but also a variety of mammals and birds. Zoonotic on humans (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommadubitatum Neumann, 1899
Amblyommacooperi Nuttall & Warburton, 1908
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily rodents, but also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommafalsomarmoreum Tonelli-Rondelli, 1935
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Reptiles, occasionally other mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommafuscum Neumann, 1907
Geographic distribution. Brazil (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on mammals, including rodents, carnivores, and marsupials. Adults usually on reptiles and amphibians. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommagemma Dönitz, 1909
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on small mammals and birds. Adults primarily on bovids, pigs, camels, and horses, but also other mammals, large birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommageomydae (Cantor, 1847)
Amblyommamalayanum Neumann, 1906
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on a variety of small mammals, birds, and reptiles. Adults primarily on tortoises, but also several mammals, including pigs, bovids, deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommahadanii Nava et al., 2014
Geographic distribution. Argentina (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, tapirs, horses, also carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommahebraeum Koch, 1844
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, goats, sheep, other ruminants, and humans; occasionally birds and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaafricae (African tick bite fever) (Jongejan et al. 2020).
Amblyommaincisum Neumann, 1906
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily tapirs, but also rodents, deer, and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommainoratum (Banks, 1909)
Geographic distribution. North and Central America (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaintegrum Karsch, 1879
Geographic distribution. India, Sri Lanka (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, but also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ears (Dilrukshi et al. 2004).
Vectored pathogens. None.
Amblyommajavanense (Supino, 1897)
Aponommasublaeve Neumann, 1899
Geographic distribution. Central, Southeastern Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily pangolins, but also rodents, and carnivores, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommalatepunctatum Tonelli-Rondelli, 1939
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily tapirs and peccaries, also marsupials and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommalatum Koch, 1844
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily reptiles, also amphibians, rodents, and shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ambylommalepidum Dönitz, 1909
Geographic distribution. Sub-Saharan Africa, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, but also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommalimbatum Neumann, 1899
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaloculosum Neumann, 1907
Geographic distribution. Sub-Saharan Africa, Australia, several islands in the Indian and South Pacific Oceans (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds and reptiles, occasionally bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommalongirostre (Koch, 1844)
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds (immature stages) and New World porcupines (adults), but also a variety of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommamaculatum Koch, 1844
Geographic distribution. Southern USA, Central and South America (Cooley 1944; Guglielmone and Robbins 2018; Lado et al. 2018).
Natural hosts. Many reptiles, birds, and mammals, including humans (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaparkeri (tidewater spotted fever) (Sumner et al. 2007; Lee et al. 2019).
Amblyommamarmoreum Koch, 1844
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on birds and mammals. Adults on tortoises. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommamixtum Koch, 1844
Geographic distribution. Southern USA, Central and South America (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Variety of mammals, including humans, also birds, amphibians, reptiles (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain spotted fever) (Bermudez and Troyo 2018).
Amblyommamoreliae (Koch, 1867)
Geographic distribution. Australia (Roberts 1970).
Natural hosts. Reptiles. Zoonotic on humans (Roberts 1970).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommanaponense (Packard, 1869)
Amblyommamantiquirense Aragão, 1908
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily mammals, including peccaries, carnivores, anteaters, marsupials, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaneumanni Ribaga, 1902
Amblyommafurcula Dönitz, 1909
Geographic distribution. Argentina, Colombia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, carnivores, pigs, peccaries, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommanuttalli Dönitz, 1909
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on a variety of mammals, birds, and reptiles. Adults primarily on tortoises. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ambylommaoblongoguttatum Koch, 1844
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. A variety of mammals, including deer, rodents, carnivores, and marsupials, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaovale Koch, 1844
Amblyommafossum Neumann, 1899
Geographic distribution. Southern USA, Central and South America (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores, rodents, tapirs, and humans. Occasionally marsupials, birds (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapacae Aragão, 1911
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily mammals, including rodents and marsupials, but also carnivores and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ambylommaparkeri Fonseca & Aragão, 1951
Geographic distribution. Brazil (Guglielmone and Robbins 2018).
Natural hosts. Primarily rodents, also carnivores, marsupials, monkeys, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaparvum Aragão, 1908
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Wide variety of mammals, including humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapaulopunctatum Neumann, 1899
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily pigs, but also hippopotamuses, carnivores, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapecarium Dunn, 1933
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Peccaries, also deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapersonatum Neumann, 1901
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Rhinoceroses, bovids. Zoonotic on humans(Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapostoculatum Neumann, 1899
Geographic distribution. Australia (Roberts 1970).
Natural hosts. Marsupials. Zoonotic on humans (Roberts 1970).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapseudoconcolor Aragão, 1908
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily armadillos, also marsupials and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommapseudoparvum Guglielmone et al., 1990
Geographic distribution. Argentina (Guglielmone and Robbins 2018).
Natural hosts. Caviomorph rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommaromitii Tonelli-Rondelli, 1939
Amblyommatasquei Floch & Adonnenc, 1940
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Rodents, marsupials. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommarotundum Koch, 1844
Geographic distribution. Southern USA, Central and South America, Pacific Islands (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Reptiles and amphibians, occasionally birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommasabanerae Stoll, 1890
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily reptiles, including tortoises, also amphibians, rodents, and marsupials. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommascalpturatum Neumann, 1906
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including tapirs, pigs, anteaters, peccaries, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommasculptum (Berlese, 1888)
Geographic distribution. South America (Martins et al. 2016; Guglielmone and Robbins 2018).
Natural hosts. Several mammals, including capybaras and humans, and birds (Osava et al. 2016; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment
Site in human host. Skin.
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain Spotted Fever) (Ramírez-Hernández et al. 2020).
Amblyommasparsum Neumann, 1899
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatapirellum Dunn, 1933
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Tapirs, peccaries, marsupials, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatenellum Koch, 1844
Amblyommaimitator Kohls, 1958
Geographic distribution. Southern USA, Central America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, peccaries, horses, marsupials, carnivores, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatestudinarum Koch, 1844
Geographic distribution. Central and Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, birds, and reptiles (Guglielmone and Robbins 2018),
Route of infection. Exposure to larval, nymph, or adult ticks in the environment
Site in human host. Skin, ear (Nakao et al. 2017).
Vectored pathogens. Dabie bandavirus (severe fever with thrombocytopenia syndrome Virus, SFTSV) (Sato et al. 2021).
Amblyommatholloni Neumann, 1899
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, primarily elephants, and birds and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatigrinum Koch, 1844
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Primarily carnivores, also rodents and ungulates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatonelliae Nava et al., 2014
Geographic distribution. South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids and equids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaricketsii (Rocky Mountain spotted fever) (Tarragona et al. 2016).
Amblyommatriguttatum Koch, 1844
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Primarily marsupials, also horses, bovids, carnivores, lagomorphs, rodents, humans, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommatriste Koch, 1844
Geographic distribution. Southern USA, Central and South America (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, primarily bovids, deer, and carnivores, and birds. Zoonotic on humans (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaparkeri (Tidewater spotted fever) (Silveira et al. 2007).
Amblyommatuberculatum Marx in Hubbard, 1894
Geographic distribution. Southeastern USA (Cooley 1944; Guglielmone and Robbins 2018).
Natural hosts. Tortoises. Zoonotic on humans (Cooley 1944; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Amblyommavariegatum (Fabricius, 1794)
Geographic distribution. Africa, Middle East, Caribbean (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, primarily bovids, also humans, birds, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaafricae (African tick bite fever) (Dantas-Torres et al. 2012).
Amblyommavarium Koch, 1844
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily sloths, also marsupials, tapirs, carnivores, and rodents, also reptiles and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Bothriocroton Keirans et al., 1994
Bothriocrotonauruginans (Schülze, 1938)
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Marsupials, occasionally carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Bothriocrotonhydrosauri (Denny, 1843)
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Reptiles, occasionally bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Dermacentor Koch, 1844
Dermacentoralbipictus (Packard, 1869)
Ixodesnigrolineatus Packard, 1869
Geographic distribution. North and Central America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily cattle, deer, and horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Babesiaduncani (babesiosis) (Swei et al. 2019).
Dermacentorandersoni Stiles, 1908
Dermacentorvenustus Marx in Neumann 1897
Geographic distribution. Rocky Mountain region of North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including humans (Eisen 2007; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment
Site in human host. Skin
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain spotted fever), Francisellatularensis (tularemia), Colorado tick fever virus; also implicated in tick paralysis (Eisen 2007).
Dermacentoratrosignatus Neumann, 1906
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Mariana et al. 2008).
Vectored pathogens. None.
Dermacentorauratus Supino, 1897
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily pigs, but also a variety of other mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Ariyarathne et al. 2011).
Vectored pathogens.Rickettsiasibirica (Siberian tick typhus) (Dantas-Torres et al. 2012).
Dermacentorbellulus (Schülze, 1933)
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents, also tree shrews, carnivores, lagomorphs, and birds. Adults are primarily on pigs, also carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorcircumguttatus Neumann, 1897
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily elephants, also duikers, pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorcompactus Neumann, 1901
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily pigs, but also a variety of other mammals and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Mariana et al. 2008).
Vectored pathogens. None.
Dermacentorhunteri Bishopp, 1912
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, also deer, lagomorphs, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorimitans Warburton, 1933
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Peccaries, deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorlatus Cooley, 1937
Geographic distribution. Central America (Guglielmone and Robbins 2018).
Natural hosts. Primarily tapirs, also carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorlimbooliati Apanaskevich & Apanaskevich, 2015
Geographic distribution. Malaysia, Vietnam (Apanaskevich and Apanaskevich 2015).
Natural hosts. Pigs. Zoonotic on humans (Apanaskevich and Apanaskevich 2015).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentormarginatus (Sulzer, 1776)
Geographic distribution. Europe, western and central Asia, northern Africa (Rubel et al. 2016; Guglielmone and Robbins 2018).
Natural hosts. Many mammals, including humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaraoultii, Omsk hemorrhagic fever virus (Dantas-Torres et al. 2012).
Dermacentornitens Neumann, 1897
Geographic distribution. Southern USA, Central and South America, Caribbean (Guglielmone and Robbins 2018).
Natural hosts. Horses, occasionally other mammals, reptiles, and amphibians. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorniveus Neumann, 1897
Geographic distribution. Central Asia, China, Russia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including ungulates, rodents, lagomorphs, hedgehogs, and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentornuttalli Olenev, 1929
Geographic distribution. Eastern Russia, Mongolia, China (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on rodents, lagomorphs, hedgehogs. Adults primarily on ungulates and horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiasibirica (Siberian tick typhus), Francisellatularensis (tularemia), Crimean-Congo hemorrhagic fever virus (Gui et al. 2021; Kulakova et al. 2014).
Dermacentoroccidentalis Marx in Curtice, 1892
Geographic distribution. Pacific coastal areas of Mexico and USA (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Immature stages primarily on rodents and lagomorphs. Adults on cattle, deer, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaphlipii (Pacific Coast tick fever) (Padgett et al. 2016).
Dermacentorparumapertus Neumann, 1901
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Lagomorphs, rodents, bovids, deer, carnivores, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorraskemensis Pomerantsev, 1946
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Bovids, carnivores, rodents, lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorreticulatus (Fabricius, 1794)
Dermacentorpictus Hermann, 1804
Geographic distribution. Europe and western Asia (Rubel et al. 2016; Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents, lagomorphs, hedgehogs, rarely birds and reptiles, and amphibians. Adults primarily on canids, also ungulates, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaslovaca (tick-borne lymphandenopathy, TIBOLA), Rickettsiaraoultii, Omsk hemorrhagic fever virus (Földvári et al. 2016).
Dermacentorrhinocerinus (Denny, 1843)
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily rhinoceroses, occasionally other mammals and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorsilvarum Olenev, 1931
Dermacentorasiaticus Emel’yanova & Kozlovskaya, 1967
Geographic distribution. Eastern Russia, China, Mongolia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, sheep, dogs, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiasibirica (Siberian tick typhus), Rickettsiaraoultii (Cao et al. 2008).
Dermacentorsimilis Lado, Glon, et Klompen, 2021
Geographic distribution. North America, west of the Rocky Mountains (Lado et al. 2021).
Natural hosts. Several groups of mammals, including humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain spotted fever), Francisellatularensis (tularemia); also implicated in tick paralysis (Wikswo et al. 2014; Moraru 2019; Mullen and Durden 2019).
Dermacentorsteini (Schülze, 1933)
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily pigs, but also a variety of other mammals and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Mariana et al. 2008).
Vectored pathogens. None.
Dermacentortamokensis Apanaskevich & Apanaskevich, 2016
Geographic distribution. Southeast Asia (Apanaskevich and Apanaskevich 2016; Guglielmone and Robbins 2018).
Natural hosts. Pigs. Zoonotic on humans (Guglielmone and Robbins 2018)
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Dermacentorvariabilis (Say, 1821)
Dermacentorelectus Koch, 1844
Geographic distribution. Eastern North America (Guglielmone and Robbins 2018; Lado et al. 2021).
Natural hosts. Several groups of mammals, including humans, and birds. (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Grady et al. 2011).
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain spotted fever), Francisellatularensis (tularemia); also implicated in tick paralysis (Ammerman et al. 2004; Dergousoff and Chilton 2012; Moraru 2019; Mullen and Durden 2019).
Genus Haemaphysalis Koch, 1844
Haemaphysalisaculeata Lavarra, 1904
Geographic distribution. India, Sri Lanka (Guglielmone and Robbins 2018).
Natural hosts. Chevrotains, bovids, deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest Disease virus (Sharma et al. 2019).
Haemaphysalisanomala Warburton, 1913
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018),
Natural hosts. Immature stages on rodents and small birds. Adults on bovids, deer, carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisaponommoides Warburton, 1913
Geographic distribution. China, India, Nepal (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on rodents, shrews, birds. Adults on mammals, primarily bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisbancrofti Nuttall & Warburton, 1915
Geographic distribution. Australia, Indonesia, Papua New Guinea (Guglielmone and Robbins 2018).
Natural hosts. Primarily marsupials, but also a variety of other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisbirmaniae Supino, 1897
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Bovids, deer, pigs, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisbispinosa Neumann, 1897
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids and carnivores, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest disease virus (Sharma et al. 2019).
Haemaphysaliscampanulata Warburton, 1908
Geographic distribution. Central and Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents. Adults on mammals, primarily carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliscaucasica Olenev, 1928
Geographic distribution. Eastern Europe, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including lagomorphs, carnivores, rodents, and bovids, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliscelebensis Hoogstral et al., 1965
Geographic distribution. Indonesia (Guglielmone and Robbins 2018).
Natural hosts. Primarily pigs, bovids, deer, and horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalischordeilis (Packard, 1869)
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds, also mammals including bovids, horses, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliscolasbelcouri (Santos Dias, 1958)
Geographic distribution. China, Vietnam, Laos (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids and deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisconcinna Koch, 1844
Geographic distribution. Palearctic (Guglielmone and Robbins 2018; Kiewra et al. 2019).
Natural hosts. Small mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018; Kiewra et al. 2019).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Francisellatularensis (tularemia), tick-borne encephalitis viruses (TBE) (Kiewra et al. 2019).
Haemaphysaliscornigera Neumann, 1897
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, carnivores, shrews, and tree shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiajaponica (Japanese spotted fever) (Li et al. 2019).
Haemaphysaliscuspidata Warburton, 1910
Geographic distribution. India, Sri Lanka (Guglielmone and Robbins 2018).
Natural hosts. Many groups of mammals, including ungulates, carnivores, rodents, lagomorphs, shrews, and non-human primates, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest disease virus (Sharma et al. 2019).
Haemaphysalisdarjeeling Hoogstraal & Dhanda, 1970
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, pigs, and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisdoenitzi Warburton & Nuttall, 1909
Geographic distribution. Southeast Asia, Japan, Russia, Australia (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds, occasionally lagomorphs and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliselliptica (Koch, 1844)
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily carnivores, also rodents, elephant shrews, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliselongata Neumann, 1897
Geographic distribution. Madagascar (Guglielmone and Robbins 2018).
Natural hosts. Primarily tenrecs, also carnivores and hedgehogs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliserinacei Pavesi, 1884
Haemaphysalisnumidiana Neumann, 1905
Haemaphysaliserinaceitaurica Pospelova-Shtrom, 1939
Geographic distribution. Europe, northern Africa, Russia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily hedgehogs and carnivores, also lagomorphs and bovids, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisflava Neumann, 1897
Geographic distribution. East Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiajaponica (Japanese spotted fever) (Li et al. 2019).
Haemaphysalisheinrichi Schülze, 1939
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, carnivores, rodents, and shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalishirsuta Hoogstraal et al., 1966
Geographic distribution. Indonesia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalishoodi Warburton & Nuttall, 1909
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds, also mammals including bovids, non-human primates, rodents, carnivores, and lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalishumerosa Warburton & Nuttall, 1909
Geographic distribution. Indonesia, Australia (Guglielmone and Robbins 2018).
Natural hosts. Primarily marsupials, also monotremes, rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalishylobatis Schülze, 1933
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalishystricis Supino, 1897
Haemaphysalisnishiyamai Sugimoto, 1935
Haemaphysalistrispinosa Tounamoff, 1941
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiajaponica (Japanese spotted fever) (Li et al. 2019).
Haemaphysalisindoflava Dhanda & Bhat, 1968
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Bovids, pigs, carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisinermis Birula, 1895
Geographic distribution. Southern Europe, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds, also rodents, shrews, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisintermedia Warburton & Nuttall, 1909
Geographic distribution. Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisjaponica Warburton, 1908
Haemaphysalisjaponicadouglasi Nuttall & Warburton, 1915
Geographic distribution. Southeast Asia, Japan, Russia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including deer, carnivores, lagomorphs, pigs, horses, bovids, and hedgehogs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisjuxtakochi Cooley, 1946
Haemaphysaliskohlsi Aragão & Fonseca, 1951
Geographic distribution. USA, Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including deer, peccaries, bovids, horses, carnivores, marsupials, rodents, and lagomorphs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliskitaokai Hoogstraal, 1969
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, horses, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysaliskoningsbergeri Warburton & Nuttall, 1909
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalislagrangei Larrousse, 1925
Haemaphysalishystricisindochinensis Phan Trong, 1977
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisleachi (Audouin, 1826)
Geographic distribution. Africa (Apanaskevich et al. 2007; Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores, bovids, pigs, non-human primates, hedgehogs, and rodents, and birds. Zoonotic on humans (Apanaskevich et al. 2007; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaconorii (boutonneuse fever) (Apanaskevich et al. 2007).
Haemaphysalisleporispalustris Packard, 1869
Geographic distribution. North, Central, and South America (Guglielmone and Robbins 2018; Sánchez-Montes et al. 2020).
Natural hosts. Primarily rabbits, also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalislongicornis Neumann, 1901
Geographic distribution. East Asia, Australia, New Zealand, Pacific Islands, eastern North America (Beard et al. 2018; Guglielmone and Robbins 2018; Wormser et al. 2020).
Natural hosts. Mammals, including sheep, deer, and horses, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Choi et al. 2018).
Vectored pathogens. Dabie bandavirus (severe fever with thrombocytopenia syndrome vrus, SFTSV), Rickettsiajaponica (Japanese spotted fever) (Li et al. 2019; Sato et al. 2021).
Haemaphysalismageshimaensis Saito & Hoogstraal, 1973
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, carnivores, pigs, rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalismegaspinosa Saito, 1969
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Deer, carnivores, horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalismjoebergi Warburton, 1926
Geographic distribution. Indonesia (Guglielmone and Robbins 2018).
Natural hosts. Deer, bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalismontgomeryi Nuttall, 1912
Geographic distribution. Central and Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, rodents, camels, deer, horses, and hedgehogs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisnadchatrami Hoogstraal et al., 1965
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Rodents, bovids, deer, pigs, carnivores, horses, tapirs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisnepalensis Hoogstraal, 1962
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Bovids, carnivores, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisnovaeguineae Hirst, 1914
Geographic distribution. Australia, Papua New Guinea (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, marsupials, carnivores, horses, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisobesa Larrousse, 1925
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalispapuana Thorell, 1883
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including pigs, deer, musk deer, carnivores, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisparaleachi Camicas et al. 1983
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Carnivores, rodents, bovids, non-human primates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisparmata Neumann, 1905
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids, rarely reptiles and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisparva (Neumann, 1897)
Haemaphysalisotophila Schülze, 1919
Geographic distribution. Europe, northern Africa, western Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including hedgehogs, carnivores, lagomorphs, rodents, and humans, birds, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalispunctata Canestrini & Fanzago, 1878
Haemaphysalispunctataautumnalis Schülze, 1919
Geographic distribution. Europe, northern Africa, western and central Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, birds, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisqinghaiensis Teng, 1980
Geographic distribution. China (Guglielmone and Robbins 2018).
Natural hosts. Bovids, horses, lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisramachandrai Dhanda et al., 1970
Geographic distribution. India, Nepal (Guglielmone and Robbins 2018).
Natural hosts. Deer, bovids, carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisroubaudi Toumanoff, 1940
Geographic distribution. Vietnam (Guglielmone and Robbins 2018).
Natural hosts. Deer. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalissemermis Neumann, 1901
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Chevrotains, deer, pigs, carnivores, tapirs, rodents, tree shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisshimoga Trapido & Hoogstraal, 1964
Haemaphysaliscornigeravietnama Phan Trong, 1977
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, deer, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalissilacea Robinson, 1912
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018)
Natural hosts. Mammals, including bovids, elephant shrews, rhinoceroses, carnivores, lagomorphs, and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisspinigera Neumann, 1897
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest Disease virus (Varma et al. 1960; Sharma et al. 2019).
Haemaphysalissulcata Canestrini & Fanzago, 1878
Haemaphysalischolodkovskyi Olenev. 1928
Geographic distribution. Europe, North Africa, Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids, but also carnivores, rodents, lagomorphs, bats, hedgehogs, and humans, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Haemaphysalisturturis Nuttall & Warburton, 1915
Geographic distribution. India, Sri Lanka (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest disease virus (Sharma et al. 2019).
Haemaphysaliswellingtoni Nuttall & Warburton, 1908
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily birds, occasionally mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest disease virus (Sharma et al. 2019).
Genus Hyalomma Koch, 1844
Hyalommaaegyptium (Linnaeus, 1758)
Geographic distribution. Europe, North Africa, Middle East, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily tortoises, but also other reptiles and mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaturcica (tick-borne relapsing fever) (Güner et al. 2004).
Hyalommaalbiparmatum Schülze, 1919
Geographic distribution. East Africa (Apanaskevich and Horak 2008; Guglielmone and Robbins 2018).
Natural hosts. Many mammals, primarily wild ungulates, also lagomorphs and birds. Zoonotic on humans (Apanaskevich and Horak 2008; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaconorii (boutonneuse fever) (Apanaskevich and Horak 2008).
Hyalommaanatolicum Koch, 1844
Geographic distribution. North Africa, Middle East, Central Asia (Vatansever 2017a; Guglielmone and Robbins 2018).
Natural hosts. Mammals, including cattle, horses, camels, sheep, goats, and humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Crimean-Congo hemorrhagic fever virus (Kassari et al. 2020).
Hyalommaasiaticum Schülze & Schlottke, 1930
Hyalommaasiaticumkozlovi Olenev, 1931
Geographic distribution. Central Asia, Middle East (Guglielmone and Robbins 2018; Vatansever 2017b).
Natural hosts. Mammals, including bovids, camels, rodents, lagomorphs, and hedgehogs, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiasibiricamongolitimonae, Coxiellaburnetti (Q fever), and possibly Crimean-Congo Hemorrhagic Fever virus (Ramos et al. 2013; Batu et al. 2020; Kassari et al. 2020).
Hyalommabrevipunctatum Sharif, 1928
Geographic distribution. Southeast and Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, camels, horses, rodents, carnivores, shrews, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommadromedarii Koch, 1844
Ixodescamelinus Fischer von Waldheim, 1823
Ixodesarenicola Eichwald, 1830
Ixodestrilineatus Lucas, 1844
Ixodescinctus Lucas, 1844
Hyalommayakimovi Olenev, 1931
Hyalommayakimovipersiacum Olenev, 1931
Hyalommadelphy Schülze and Gossel in Schülze, 1936
Geographic distribution. Africa, Middle East, Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily camels, but also other mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Crimean-Congo hemorrhagic fever virus (Champour et al. 2016).
Hyalommaexcavatum Koch, 1844
Geographic distribution. North Africa, Mediterranean Europe, Middle East, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, camels, lagomorphs, rodents, hedgehogs, and humans, birds, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommaglabrum Delpy, 1949
Geographic distribution. South Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on lagomorphs, carnivores, hyrax, rodents, and birds. Adults on bovids, occasionally carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommahussaini Sharif, 1928
Geographic distribution. India, Pakistan, Myanmar (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on rodents and shrews. Adults on bovids, camels, pigs, carnivores, and horses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommaimpeltatum Schülze & Schlottke, 1930
Geographic distribution. Africa, Middle East, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, camels, horses, rhinoceroses, carnivores, and rodents, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalmonnaisaaci Sharif, 1928
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on lagomorphs, deer, carnivores, and birds. Adults primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommalustanicum Koch, 1844
Geographic distribution. Mediterranean Europe and Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids and lagomorphs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommamarginatum Koch, 1844
Geographic distribution. Europe, North Africa, Middle East, Central Asia (Estrada-Peña et al. 2012; Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, and birds. Immature stages are primarily on small mammals and birds. Adults primarily on ungulates (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host: Skin.
Vectored pathogens. Crimean-Congo hemorrhagic fever virus (Gargili et al. 2013; Kassari et al. 2020).
Hyalommarufipes Koch, 1844
Geographic distribution. Africa, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Immature stages are primarily on birds and lagomorphs. Adults are primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Crimean-Congo hemorrhagic fever virus (Hoogstraal 1979).
Hyalommaschulzei Olenev, 1931
Geographic distribution. Middle East, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents, hedgehogs, and lagomorphs. Adults primarily on camels, occasionally bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommascupense Schülze, 1919
Hyalommadetritum Schülze, 1919
Hyalommadetritumdardanicum Schülze & Schlottke, 1930
Hyalommauralense Schülze & Schlottke, 1930
Hyalommavolgense Schülze & Schlottke, 1930
Geographic distribution. Europe, North Africa, Middle East, Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Bovids, camels, horses, pigs, deer, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Hyalommatruncatum Koch, 1844
Hyalommatransiens Schülze, 1919
Geographic distribution. Africa, Saudi Arabia, Yemen (Apanaskevich and Horak 2008; Guglielmone and Robbins 2018).
Natural hosts. Many groups of mammals, birds, and reptiles. Immature stages primarily on rodents and lagomorphs. Adults primarily on domestic and wild ungulates. Zoonotic on humans (Apanaskevich and Horak 2008; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment
Site in human host. Skin
Vectored pathogens. Crimean-Congo hemorrhagic fever virus, Rickettsiaconnorii (boutonneuse fever), Coxiellaburnetii (Q fever) (Apanaskevich and Horak 2008).
Hyalommaturanicum Pomerantzev, 1946
Geographic distribution. North Africa, Middle East, Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, lagomorphs, camels, pigs, horses, humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Ixodes Latreille, 1795
Ixodesacuminatus Neumann, 1901
Geographic distribution. Europe, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, but also other mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesacutitarsus (Karsch, 1880)
Ixodesgigas Warburton, 1910
Geographic distribution. Southeast Asia, Japan, India (Guglielmone and Robbins 2018).
Natural hosts. Immature stages are typically on rodents; adults on ungulates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesangustus Neumann, 1899
Geographic distribution. North America, Russia, Japan (Spencer 1963; Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, but also other mammals and birds. Zoonotic on humans (Spencer 1963; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesapronophorus Schülze, 1924
Geographic distribution. Europe, Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, but also other mammals, reptiles, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesasanumai Kitaoka, 1973
Geographic distribution. Japan (Okono 2010).
Natural hosts. Reptiles, rarely mammals and birds. Zoonotic on humans (Okono 2010).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesaustraliensis Neumann, 1904
Geographic distribution. Australia (Kwak 2018).
Natural hosts. Marsupials, dogs, bovids. Zoonotic on humans (Kwak 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesbaergi Cooley & Kohls, 1942
Geographic distribution. North America (Walker et al. 1998).
Natural hosts. Passerine birds. Zoonotic on humans (Walker et al. 1998).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesbanksi Bishopp, 1911
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Rodents, carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesboliviensis Neumann, 1904
Ixodesbicornis Neumann, 1906
Geographic distribution. Central and South America (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesbrunneus Koch, 1844
Ixodesricinuscalifornicus Banks, 1908
Geographic distribution. Western Hemisphere (Guglielmone and Robbins 2018).
Natural hosts. Birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescanisuga Johnston, 1849
Geographic distribution. Europe (Guglielmone and Robbins 2018).
Natural hosts. Carnivores; immature stages occasionally on birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescavipalpus Nuttall & Warburton, 1908
Ixodesrubicunduslimbatus Neumann, 1908
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Ungulates, primarily cattle. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescolumnae Takada & Fujita, 1992
Geographic distribution. Japan (Takada and Fujita 1992).
Natural hosts. Rodents, birds. Zoonotic on humans (Takada and Fujita 1992).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesconfusus Roberts, 1960
Geographic distribution. Australia, Papua New Guinea (Roberts 1970).
Natural hosts. Ungulates, equids, marsupials. Zoonotic on humans (Roberts 1970).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescookei Packard, 1869
Ixodescruciarius Fitch, 1872
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Powassan virus lineage I (Khan et al. 2019).
Ixodescornuatus Roberts, 1960
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores and rodents, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescrenulatus Koch, 1844
Geographic distribution. Europe, Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, carnivores, lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodescumulatimpunctatus Schülze, 1943
Ixodespseudorasus Arthur & Burrow, 1957
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesdentatus Marx in Neumann, 1899
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Immature stages on a variety of mammals and birds; adults on mammals, primarily lagomorphs and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeseichhorni Nuttall, 1916
Geographic distribution. Southeast Asia, Australia, Pacific Islands (Guglielmone and Robbins 2018).
Natural hosts. Birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesfecialis Warburton & Nuttall, 1909
Geographic distribution. Australia, Papua New Guinea (Domrow and Derrick 1964).
Natural hosts. Marsupials. Zoonotic on humans (Domrow and Derrick 1964).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment
Site in human host. Skin
Vectored pathogens. None
Ixodesfestai Rondelli, 1926
Geographic distribution. Southern Europe, northern Africa (Guglielmone and Robbins 2018).
Natural hosts. Birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesfrontalis (Panzer, 1798)
Geographic distribution. Europe, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesgibbosus Nuttall, 1916
Geographic distribution. Southern, eastern Europe, Middle East (Guglielmone and Robbins 2018).
Natural hosts. Ungulates, primarily bovids, rarely birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesgranulatus Supino, 1897
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, birds, reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeshexagonus Leach, 1815
Geographic distribution. Europe (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily hedgehogs, also birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesholocyclus Neumann, 1899
Geographic distribution. East coastal Australia (Guglielmone and Robbins 2018).
Natural hosts. Marsupials, primarily bandicoots, also livestock, cats, dogs, and humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaaustralis (Queensland tick typhus); also implicated in tick paralysis (Hall-Mendelin et al. 2011; Stewart et al. 2017).
Ixodeskaschmiricus Pomerantsev, 1948
Geographic distribution. Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids, carnivores, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeskazakstani Olenev & Sorokoumov, 1934
Geographic distribution. Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Several mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeskingi Bishopp, 1911
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including carnivores, rodents, lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeskohlsi Arthur, 1955
Geographic distribution. Australia (Roberts 1970).
Natural hosts. Birds. Zoonotic on humans (Roberts 1970).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeslaguri Olenev, 1929
Geographic distribution. Central and Eastern Europe, Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, lagomorphs, shrews, hedgehogs, carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesmarxi Banks, 1908
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents; also birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Powassan virus lineage I (Khan et al. 2019).
Ixodesmonospinosus Saito, 1968
Geographic distribution. Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, deer, rodents, carnivores, shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesmuniensis Arthur & Burrow, 1957
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, giraffes, hyrax, carnivores, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesmuris Bishopp & Smith, 1937
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesmyrmecobii Roberts, 1962
Geographic distribution. Australia (Guglielmone and Robbins 2018).
Natural hosts. Marsupials, rarely other mammals, birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesnipponensis Kitaoka & Saito, 1967
Geographic distribution. Southeast Asia, Japan, Russia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores, bovids, deer, lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesovatus Neumann, 1899
Ixodesjaponensis Neumann, 1904
Ixodesfrequens Ogura & Takada, 1927
Ixodescarinatus Kishida, 1930
Ixodeslindbergi Santos Dias, 1959
Geographic distribution. Central, Eastern, Southeastern Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including rodents, lagomorphs, carnivores, shrews, humans, and birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Iwasaki et al. 2007).
Vectored pathogens.Rickettsiajaponica (Japanese spotted fever) (Li et al. 2019).
Ixodespacificus Cooley & Kohls, 1943
Ixodescalifornicus Banks, 1904
Geographic distribution. Western North America (Padgett and Lane 2001; Guglielmone and Robbins 2018).
Natural hosts. Small mammals, birds, and reptiles. Zoonotic on humans (Padgett and Lane 2001; Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaburgdorferi (Lyme disease), B.miyamotoi (tick-borne relapsing fever), Anaplasmaphagocytophilum (human granulocytic anaplasmosis) (Padgett and Lane 2001).
Ixodespararicinus Keirans & Clifford in Keirans et al. 1985
Geographic distribution. Argentina, Colombia, Peru (Saracho-Bottero et al. 2018).
Natural hosts. Immature stages are primarily on small mammals and birds. Adults are on ungulates, including bovids, peccaries, and deer. Zoonotic on humans (Saracho-Bottero et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodespavlovskyi Pomerantzev, 1946
Geographic distribution. Central Asia, Russia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Birds and mammals, including rodents, lagomorphs, carnivores, hedgehogs, shrews, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodespersulcatus (Schülze, 1930)
Geographic distribution. Europe, Northern Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including dogs, deer, rodents, lagomorphs, and humans, and ground-nesting birds (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Kogoashiwa et al. 2009),
Vectored pathogens.Borreliamiyamotoi (tick-borne relapsing fever), B.garinii, tick-borne encephalitis viruses (TBE) (Jaenson et al. 2016).
Ixodespetauristae Warburton, 1933
Geographic distribution. India, Sri Lanka (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodespilosus Koch, 1844
Geographic distribution. Southern Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily ungulates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesrageaui Arthur, 1958
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Non-human primates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesrasus Neumann, 1899
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including ungulates, carnivores, rodents, and hyrax, and birds, Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesredikorzevi Olenev, 1927
Ixodestheodori Warburton, 1927
Geographic distribution. Europe, North Africa, Middle East, Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including rodents, hedgehogs, lagomorphs, and carnivores, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesricinus (Linnaeus, 1758)
Acarusreduvius Linnaeus, 1758
Geographic distribution. Europe, North Africa, Middle East, northern Asia (Guglielmone and Robbins 2018).
Natural hosts. Many mammals, including humans, and birds. Immature stages are typically on small mammals, reptiles, and birds. Adults are on ungulates and dogs (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaburgdorferi sensu lato (Lyme disease), B.miyamotoi (tick-borne relapsing fever), Coxiellaburnetii (Q fever), Babesiadivergens (babesiosis), tick-borne encephalitis viruses (TBE), louping ill virus (Davidson et al. 1991; Gern 2005; Rizzoli et al. 2014).
Ixodesrubicundus Neumann, 1904
Geographic distribution. South Africa (Guglielmone and Robbins 2018)y.
Natural hosts. Mammals, including ungulates, rodents, lagomorphs, and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesrugosus Bishopp, 1911
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores, but also opossums and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesscapularis Say, 1821
Ixodesozarkus Cooley, 1944
Ixodesdammini Spielman et al., 1979
Geographic distribution. Eastern and Midwestern North America (Guglielmone and Robbins 2018).
Natural hosts. Immature stages are primarily on rodents and other small mammals, reptiles, small birds. Adults are on ungulates (primarily deer) and dogs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaburgdorferi sensu lato and B.mayonii (Lyme disease), B.miyamotoi (tick-borne relapsing fever), Babesiamicroti (babesiosis), Anaplasmaphagotocytophilum (human granulocytic anaplasmosis), deer tick virus (Powassan virus lineage II) (Nelder et al. 2016; Westblade et al. 2017; Khan et al. 2019; Wolf et al. 2020).
Ixodesschillingsi Neumann, 1901
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Non-human primates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodessculptus Neumann, 1904
Geographic distribution. Central Asia, Russia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Primarily rodents and lagomorphs, rarely ungulates and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodessinensis Teng, 1977
Geographic distribution. China (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including ungulates, rodents, and lagomorphs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodessoricis Gregson, 1942
Geographic distribution. North America (Spencer 1963).
Natural hosts. Shrews and rodents. Zoonotic on humans (Spencer 1963).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesspinicoxalis Neumann, 1899
Geographic distribution. Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, tree shrews, rodents, and carnivores, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesspinipalpis Hawden et Nuttall in Nutall, 1916
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, but also lagomorphs and carnivores, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodestancitarius Cooley & Kohls, 1942
Geographic distribution. Mexico (Guglielmone and Robbins 2018).
Natural hosts. Rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Notes. The single human record from Mexico is considered tentative (Guglielmone and Robbins 2018).
Ixodestanuki Saito, 1964
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including carnivores, rodents, and ungulates. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodestasmani Neumann, 1899
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including marsupials, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodestexanus Banks, 1909
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodestrainguliceps Birula, 1895
Geographic distribution. Europe, northwestern Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily shrews, but also rodents and carnivores; birds, lizards. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesturdus Nakatsudi, 1942
Geographic distribution. Southeast Asia, Japan (Guglielmone and Robbins 2018).
Natural hosts. Birds, rarely rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesuriae White, 1852
Hyalommaputa Pickard-Cambridge, 1876
Geographic distribution. North America, Europe, Russia, southern Africa, Australia (Guglielmone and Robbins 2018).
Natural hosts. Predominately birds, but also mammals, including carnivores, rodents, and humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesvanidicus Schülze, 1943
Geographic distribution. Sub-Saharan Africa (Estrada-Pena and Jongejan 1999).
Natural hosts. Mammals, including carnivores and elephant shrews. Zoonotic on humans (Estrada-Pena and Jongejan 1999).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesventalloi Gil Collado, 1936
Geographic distribution. Europe, northern Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including carnivores, rodents, and lagomorphs; birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodesvespertilionis Koch, 1844
Geographic distribution. Europe, Africa, Asia (Guglielmone and Robbins 2018).
Natural hosts. Bats. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Ixodeswoodi Bishopp, 1911
Geographic distribution. North America (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily rodents, also carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Nosomma Schülze, 1919
Nosommamonstrosum (Nuttall & Warburton, 1908)
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Immature stage primarily on rodents and shrews. Adults primarily on bovids, deer, pics, horses, and carnivores. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Rhipicephalus Koch, 1844
Rhipicephalusannulatus (Say, 1821)
Rhipicephaluscalcaratus Birula, 1895
Geographic distribution. North America, Africa, Europe, Middle East, Central Asia (Guglielmone and Robbins 2018).
Natural hosts. Primarily cattle, but also other mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusappendiculatus Neumann, 1901
Geographic distribution. Sub-Saharan Africa (Perry et al. 1990).
Natural hosts. Mammals, including cattle, buffalo, antelope, warthogs, equids, lagomorphs, and dogs. Zoonotic on humans (Perry et al. 1990).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusarmatus Pocock, 1900
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Carnivores, bovids, and lagomorphs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusaurantiacus Neumann, 1907
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Bovids, pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusaustralis Fuller, 1899.
Geographic distribution. Southeast Asia, Australia, Pacific Islands (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusbequaerti Zumpt, 1950
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Bovids, pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusbursa Canestrini er Fanzago, 1878
Geographic distribution. Southern Europe, North Africa, Middle East, Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluscarnivoralis Walker, 1966
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily felids, also other mammals including bovids and hyrax. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluscomplanatus Neumann, 1911
Geographic distribution. West Africa (Guglielmone and Robbins 2018).
Natural hosts. Pigs, bovids, carnivores, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluscompositus Neumann, 1897
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on rodents. Adults primarily on bovids, pigs, carnivores, horses, rhinoceroses. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusdecoloratus Koch, 1844
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily bovids, also other mammals, birds, and tortoises. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusdistinctus Bedford, 1932
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Primarily hyrax, also lagomorphs, carnivores, rodents, and elephant shrews. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusevertsi Neumann, 1897
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusfollis Dönitz, 1910
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, carnivores, horses, rhinoceroses, hyrax, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusfulvus Neumann, 1913
Geographic distribution. Central and northern Africa (Guglielmone and Robbins 2018).
Natural hosts. Bovids, camels, rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusgertrudae Feldman-Muhsam, 1960
Geographic distribution. Southern Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, birds, and reptiles. Immature stages primarily on rodents. Adults primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusglabroscutatus Du Toit, 1941
Geographic distribution. South Africa (Guglielmone and Robbins 2018).
Natural hosts. Immature stages primarily on carnivores, rodents, birds. Adults primarily on lagomorphs, horses, and hyrax. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusguilhoni Morel & Vassiliades, 1963
Geographic distribution. Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Immature stages primarily on rodents, lagomorphs. Adults primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalushaemaphysaloides Supino, 1897
Geographic distribution. Central and Southeast Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including carnivores, rodents, bovids, and shrews; birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin, ear (Dilrukshi et al. 2004).
Vectored pathogens. None.
Rhipicephalushumeralis Tonelli-Rondelli, 1926
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Various groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalushurti Wilson, 1954
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, carnivores, rhinoceroses, and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusjeanneli Neumann, 1913
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, pigs, horses, rhinoceroses, and carnivores, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluskochi Dönitz, 1905
Rhipicephalusneavi Warburton, 1912
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, elephant shrews, lagomorphs, and pigs; birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluslongus Neumann, 1907
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily bovids and pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluslunulatus Neumann, 1907
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, lagomorphs, elephant shrews, and rodents; birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusmaculatus Neumann, 1901
Geographic distribution. Southern and East Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, rhinoceroses, carnivores, horses, and elephants; rarely reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusmicroplus (Canestrini, 1888)
Geographic distribution. Circumtropical (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, especially livestock; birds and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusmuehlensi Zumpt, 1943
Geographic distribution. Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluspilans Schülze, 1935
Geographic distribution. East Timor, Indonesia, Philippines (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusplanus Neumann, 1907
Rhipicephalusreichenowi Zumpt, 1943
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Immature stages primarily on rodents and lagomorphs. Adults primarily on bovids and pigs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluspraetextatus Gerstäcker, 1873
Geographic distribution. Africa, Yemen (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Immature stages primarily on rodents. Adults primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusparvus Dönitz, 1910
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluspulchellus (Gerstäcker, 1873)
Geographic distribution. East Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, especially bovids, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluspumilio Schülze, 1935
Geographic distribution. Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including hedgehogs, rodents, and lagomorphs, and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluspusillus Gil Collado, 1936
Geographic distribution. Mediterranean Europe and Africa(Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusrossicus Yakimov et Kohl-Yakimova, 1911
Geographic distribution. Eastern Europe, Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, birds, and reptiles. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalussanguineus (Latreille, 1806)
Geographic distribution. Worldwide (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, especially dogs. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiarickettsii (Rocky Mountain spotted fever), R.conorii (boutonneuse fever) (Dantas-Torres 2010; Dantas-Torres et al. 2012).
Rhipicephalusschulzei Olenev, 1929
Geographic distribution. Central and East Asia (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including rodents, lagomorphs, and carnivores; birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalussenegalensis Koch, 1844
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals and birds. Immature stages primarily on carnivores, elephant shrews, and rodents. Adults primarily on bovids, especially domestic cattle, and other mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalussimus Koch, 1844
Geographic distribution. Southern and East Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalussulcatus Neumann, 1908
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalussupertritus Neumann, 1907
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, especially bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusturanicus Pomerantzev, 1936
Geographic distribution. Hard to define but generally considered broadly distributed in Africa and Asia (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals, including humans, birds, and reptiles (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Rickettsiaconorii (boutonneuse fever) (Dantas-Torres et al. 2012).
Rhipicephaluswarburtoni Walker et Horak in Walker et al., 2000
Geographic distribution. South Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, including bovids, elephant shrews, lagomorphs, carnivores, horses, and rodents; birds. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluszambeziensis Walker et al., 1981
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Many groups of mammals and birds. Immature stages primarily on lagomorphs. Adults primarily on bovids. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephalusziemanni Neumann, 1904
Geographic distribution. Sub-Saharan Africa (Guglielmone and Robbins 2018).
Natural hosts. Mammals, primarily carnivores and rodents. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Rhipicephaluszumpti Santos Dias, 1950
Geographic distribution. Southern and Eastern Africa (Guglielmone and Robbins 2018).
Natural hosts. Several groups of mammals. Zoonotic on humans (Guglielmone and Robbins 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
●●●●●●●●●●●●● Argasidae Koch, 1844
Genus Argas Latreille, 1795
Argasmonolakensis Schwan et al. 1992
Geographic distribution. Mono Lake, California, USA (Schwan et al. 1992)
Natural hosts. Birds, primarily California gulls (Laruscalifornicus) (Schwan et al. 1992).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Argaspersicus (Oken, 1818)
Geographic distribution. Worldwide (Hoogstraal 1985).
Natural hosts. Birds. Zoonotic on humans as incidental hosts (Hoogstraal 1985).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens. Kyasanur Forest disease virus (Hoogstraal 1985).
Genus Ornithodoros Koch, 1844
Ornithodoroserraticus Lucas, 1849
Geographic distribution. Mediterranean Region (Talagrand-Reboul et al. 2018).
Natural hosts. Many mammals, including pigs, rodents, insectivores, canids, mustelids, bats. Zoonotic on humans as incidental hosts (Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliahispanica (tick-borne relapsing fever) (Boinas et al. 2014; Talagrand-Reboul et al. 2018).
Ornithodorosgraingeri Heisch & Guggisberg, 1953
Geographic distribution. Kenya (Heisch and Harvey 1953).
Natural hosts. Rodents. Zoonotic on humans as incidental hosts (Heisch and Harvey 1953; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliagraingeri (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodoroshermsi Wheeler, 1935
Geographic distribution. Western North America (Sage et al. 2017).
Natural hosts. Rodents. Zoonotic on humans as incidental hosts (Sage et al. 2017; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliahermsii (tick-borne relapsing fever) (Sage et al. 2017; Talagrand-Reboul et al. 2018).
Ornithodorosmarocanus Velu, 1919
Geographic distribution. Mediterranean Region (Vial 2009).
Natural hosts. Many mammals, including rodents, insectivores, canids, mustelids, bats. Zoonotic on humans as incidental hosts (Vial 2009; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliahispanica (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodorosmoubata Murray, 1877
Geographic distribution. Sub-Saharan Africa (Vial 2009).
Natural hosts. Pigs, poultry. Zoonotic on humans as incidental hosts (Vial 2009; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaduttoni (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodorosparkeri Cooley, 1936
Geographic distribution. Western North America (Lopez et al. 2016).
Natural hosts. Rodents, horses. Zoonotic on humans as incidental hosts (Lopez et al. 2016; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaparkeri (tick-borne relapsing fever) (Lopez et al. 2016; Talagrand-Reboul et al. 2018).
Ornithodorosrudis Karsch, 1880
Ornithodorosvenezuelensis Brumpt, 1921
Geographic distribution. Panama and South America (Faccini-Martínez Á and Botero-García 2016).
Natural hosts. Birds, primarily poultry. Zoonotic on humans as incidental hosts (Faccini-Martínez Á and Botero-García 2016; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliavenezuelensis (tick-borne relapsing fever) (Faccini-Martínez Á and Botero-García 2016; Talagrand-Reboul et al. 2018).
Ornithodorossonrai Sautet & Witkowski, 1944
Geographic distribution. Western and northern Africa (Vial 2009).
Natural hosts. Rodents, insectivores. Zoonotic on humans as incidental hosts (Vial 2009; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliacrocidurae (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodorostalajae (Guérin-Méneville, 1849)
Geographic distribution. Southern United States, Central and South America (Cooley 1945; Faccini-Martínez Á and Botero-García 2016).
Natural hosts. Many mammals. Zoonotic on humans as incidental hosts (Cooley 1945; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borrelliamazzottii (tick-borne relapsing fever) (Elelu 2018; Talagrand-Reboul et al. 2018; Moraru 2019).
Ornithodorostholozani Laboulbène & Mégnin, 1882
Geographic distribution. Middle East, North Africa, Central Asia, India (Vial 2009).
Natural hosts. Rodents, insectivores. Zoonotic on humans as incidental hosts (Vial 2009; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliapersica (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodorosturicata (Dugès, 1876)
Geographic distribution. Western and Midwestern North America, Mexico (Cooley 1945).
Natural hosts. Rodents, dogs. Zoonotic on humans as incidental hosts (Cooley 1945; Talagrand-Reboul et al. 2018).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliaturicatae (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Ornithodorosverrucosus Olenev et al., 1934
Geographic distribution. Eastern Europe (Vial 2009).
Natural hosts. Rodents. Zoonotic on humans as incidental hosts (Vial 2009).
Route of infection. Exposure to larval, nymph, or adult ticks in the environment.
Site in human host. Skin.
Vectored pathogens.Borreliacaucasica (tick-borne relapsing fever) (Talagrand-Reboul et al. 2018).
Genus Otobius Banks, 1912
Otobiusmegnini (Dugès, 1884)
Geographic distribution. Nearly worldwide wherever livestock are raised (Cooley 1945).
Natural hosts. Cattle, sheep, goats, deer, other ruminants, carnivores, rabbits. Zoonotic on humans as incidental hosts (Cooley 1945).
Route of infection. Exposure to larval or nymph ticks in the environment.
Site in human host. Ears (Cooley 1945; Naudé et al. 2001; Mazlumoglu 2018).
Vectored pathogens. None.
●●●●●●●●●●●● Mesostigmata Canestrini, 1891
●●●●●●●●●●●●● Dermanyssoidea Kolenati, 1859
●●●●●●●●●●●●●● Dermanyssidae Kolenati, 1859
Genus Dermanyssus Dugès, 1834
Dermanyssusgallinae (DeGeer, 1778)
Geographic distribution. Worldwide (Cafiero et al. 2019).
Natural hosts. Birds. Zoonotic on humans as incidental hosts (Cafiero et al. 2019).
Route of infection. Contact with infected birds (Cafiero et al. 2019).
Site in human host. Skin, ear (Rossiter 1997; Cafiero et al. 2019).
Vectored pathogens. None.
Genus Liponyssoides Hirst, 1913
Liponyssoidessanguineus (Hirst, 1914)
Geographic distribution. Worldwide (Diaz 2009).
Natural hosts. Rodents. Zoonotic on humans as incidental hosts (Diaz 2009).
Route of infection. Contact with and living among infected rodents (Diaz 2009).
Site in human host. Skin (Diaz 2009).
Vectored organism.Rickettsiaakari (rickettsialpox) (Saini et al. 2004).
●●●●●●●●●●●●●● Laelapidae Berlese, 1892
Genus Laelaps Koch, 1836
Laelapsechidnina Berlese, 1887
Geographic distribution. Worldwide (Watson 2008).
Natural hosts. Rodents, primarily rats (Rattus). Zoonotic on humans as incidental hosts (Watson 2008).
Route of infection. Contact with and living among infected rodents (Watson 2008).
Site in human host. Skin (Watson 2008).
Vectored pathogens. None.
●●●●●●●●●●●●●● Macronyssidae Oudemans, 1936
Genus Ophionyssus Mégnin, 1884
Ophionyssusnatricis (Gervais, 1844)
Geographic distribution. Worldwide (Wozniak and DeNardo 2000).
Natural hosts. Reptiles, primarily snakes, also lizards. Zoonotic on humans as incidental hosts (Schutlz 1975; Wozniak and DeNardo 2000; Amanatfard et al. 2014).
Route of infection. Contact with infected reptiles (Schutlz 1975; Amanatfard et al. 2014).
Site in human host. Skin (Schutlz 1975; Amanatfard et al. 2014).
Vectored pathogens. None.
Genus Ornithonyssus Sambon, 1928
Ornithonysusbacoti (Hirst, 1913)
Geographic distribution. Tropics and subtropics worldwide (Diaz 2009).
Natural hosts. Rodents, primarily rats (Rattus). Zoonotic on humans as incidental hosts (Diaz 2009).
Route of infection. Contact with and living among infected rodents (Diaz 2009).
Site in human host. Skin (Diaz 2009).
Vectored pathogens. None.
Ornithonyssusbursa (Berlese, 1888)
Geographic distribution. Tropics and subtropics worldwide (Diaz 2009).
Natural hosts. Birds. Zoonotic on humans as incidental hosts (Diaz 2009).
Route of infection. Contact with and living among infected birds (Diaz 2009).
Site in human host. Skin (Diaz 2009).
Vectored pathogens. None.
Ornithonyssussylviarum (Canestrini & Fanzago, 1877)
Geographic distribution. Worldwide (Murillo and Mullens 2017).
Natural hosts. Birds. Zoonotic on humans as incidental hosts (Murillo and Mullens 2017).
Route of infection. Contact with and living among infected birds (Murillo and Mullens 2017).
Site in human host. Skin (Murillo and Mullens 2017).
Vectored pathogens. None.
●●●●●●● Mandibulata Snodgrass, 1938
●●●●●●●● Pancrustacea Zrzavý & Štys, 1997
Tetraconata Dohle, 2001
●●●●●●●●● Crustacea Brünnich, 1772
●●●●●●●●●● Maxillopoda Dahl, 1956
●●●●●●●●●●● Pentastomida Diesing, 1836
●●●●●●●●●●● Porocephalidae Sambon, 1922
Genus Armillifer Sambon, 1922
Armilliferagkistrodontis Self & Kuntz, 1966
Geographic distribution. China (Chen et al. 2010; Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Natural hosts. Intermediate hosts are rodents. Definitive hosts are snakes. Zoonotic in humans as dead-end hosts (Chen et al. 2010; Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Route of infection. Ingestion of infected intermediate or reservoir host (Chen et al. 2010; Ioannou and Vamvoukaki 2019).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs (Chen et al. 2010; Ioannou and Vamvoukaki 2019).
Armilliferarmillatus Wyman, 1845
Geographic distribution. Central and western Africa (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Natural hosts. Intermediate hosts are various mammals. Definitive hosts are pythons. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Route of infection. Ingestion of infected intermediate or reservoir host (Ioannou and Vamvoukaki 2019).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs, brain, eye. (Ioannou and Vamvoukaki 2019).
Armillifergrandis Hett, 1915
Geographic distribution. Central and western Africa (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Natural hosts. Intermediate hosts are rodents. Definitive hosts are viperid snakes. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Route of infection. Ingestion of infected intermediate or reservoir host (Ioannou and Vamvoukaki 2019).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs, brain, and eye (Tappe and Büttner 2009; Ioannou and Vamvoukaki 2019).
Armillifermoniliformis (Diesing, 1835)
Geographic distribution. Southeast Asia (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Natural hosts. Intermediate hosts are various mammals. Definitive hosts are snakes. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013; Ioannou and Vamvoukaki 2019).
Route of infection. Ingestion of infected intermediate or reservoir host (Ioannou and Vamvoukaki 2019).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs, liver (Latif et al. 2011; Ioannou and Vamvoukaki 2019).
Genus Porocephalus Humboldt, 1811
Porocephaluscrotali (Humboldt, 1808)
Geographic distribution. New World (Esslinger 1962; Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are small mammals, including rodents, monkeys. Definitive hosts are snakes, primarily rattlesnakes (Crotalus). Zoonotic in humans as dead-end hosts (Esslinger 1962; Christoffersen and Assis 2013).
Route of infection. Ingestion of infected intermediate or reservoir host (Tappe and Büttner 2009).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs (Tappe and Büttner 2009).
Porocephalussubuliferum (Leuckart, 1860)
Geographic distribution. Africa (Sambon 1922; Christoffersen and Assis 2013).
Natural hosts. Intermediate and definitive hosts are snakes. Zoonotic in humans as dead-end hosts (Sambon 1922; Christoffersen and Assis 2013).
Route of infection. Ingestion of infected intermediate host (Sambon 1922).
Site in human host. Viscera (Sambon 1922; Christoffersen and Assis 2013).
Porocephalustaiwana Qui et al., 2005
Geographic distribution. Southeast Asia (Qiu et al. 2005; Yao et al. 2008; Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are unknown. Definitive hosts are snakes. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013).
Route of infection. Ingestion of infected intermediate or reservoir host (Qiu et al. 2005).
Site in human host. Disseminated disease, including greater omentum, small intestine, liver, lungs (Qiu et al. 2005; Yao et al. 2008).
●●●●●●●●●●● Linguatulidae Haldeman, 1851
Genus Linguatula Fröhlich, 1789
Linguatulaserrata Fröhlich, 1789
Geographic distribution. Worldwide (Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are sheep, bovids, rodents. Definitive hosts are felids and canids. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013).
Route of infection. Ingestion of infected intermediate or reservoir host (Tappe and Büttner 2009).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs, eyes (Tappe and Büttner 2009).
●●●●●●●●●●● Raillietiellidae Sambon, 1922
Genus Raillietiella Sambon in Vaney & Sambon, 1910
Geographic distribution. Worldwide (Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are insects. Definitive hosts are reptiles and amphibians. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013).
Route of infection. Ingestion of infected intermediate or reservoir host (Tappe et al. 2016b).
Site in human host. Disseminated infection, including the mesenteries, peritoneum, lungs (Tappe et al. 2016b).
Notes.Raillietiella isolates from human hosts have not been characterized at the species level. Cases of R.hemidactyli Hett, 1934 and R.gehyrae Bovien, 1927 from Vietnam were not confirmed morphologically (Tappe et al. 2016b).
●●●●●●●●●●● Sebekidae Sambon, 1922
Genus Leiperia Sambon, 1922
Leiperiacincinallis Sambon, in Vaney and Sambon 1910
Geographic distribution. Africa (Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are freshwater fish. Definitive hosts are crocodiles and turtles. Zoonotic in humans as dead-end hosts (Christoffersen and Assis 2013).
Route of infection. Presumably ngestion of infected intermediate or paratenic host.
Site in human host. Intestine (?) (Fain 1960, 1961)
Notes.Leiperiacincinallis has been reported from the stool of a European woman in Zaire (Fain 1960, 1961), but it is believed this may represent spurious passage after ingesting infected fish (Christoffersen and Assis 2015).
Genus Sebekia Sambon, 1922
Geographic distribution. Australia, South America, Southeast Asia, southern Africa (Christoffersen and Assis 2013).
Natural hosts. Intermediate hosts are freshwater fish. Definitive hosts are crocodiles and snakes (Christoffersen and Assis 2013).
Route of infection. Presumably by ingestion of infected intermediate or paratenic host.
Site in human host. Skin (Mairena et al. 1989).
Notes. A single human case of Sebekia, manifesting as dermatitis in a woman in Costa Rica (Mairena et al. 1989) was not identified to the species level.
●●●●●●●●● Hexapoda Latreille, 1825
●●●●●●●●●● Insecta Linnaeus, 1758
●●●●●●●●●●● Hemiptera Linnaeus, 1758
●●●●●●●●●●●● Reduviidae Latreille, 1807
Genus Meccus Stål, 1859
Meccuspallidipennis (Stål, 1872)
Geographic distribution. Mexico (Franzim-Junior et al. 2018).
Natural hosts. Various mammals. Zoonotic on humans (Franzim-Junior et al. 2018).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas Disease, American trypanosomiasis) (Franzim-Junior et al. 2018).
Genus Panstrongylus Berg, 1879
Panstrongylusgeniculatus (Latreille, 1811)
Geographic distribution. Central and South America (Melo et al. 2018).
Natural hosts. Armadillos. Zoonotic on humans (Melo et al. 2018).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Panstrongylusmegistus (Burmeister, 1835)
Geographic distribution. Argentina, Bolivia, Brazil, Paraguay, Uruguay (Jurberg and Galvão 2006).
Natural hosts. Various mammals. Zoonotic on humans (Jurberg and Galvão 2006).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Jurberg and Galvão 2006).
Genus Paratriatoma Barber, 1938
Paratriatomahirsuta Barber, 1938
Geographic distribution. Southwestern USA, Mexico (Bern et al. 2011).
Natural hosts. Rodents. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Rhodnius Stål, 1859
Rhodniusprolixus Stål, 1859
Geographic distribution. Central and South America (Jurberg and Galvão 2006).
Natural hosts. Various mammals. Zoonotic on humans (Jurberg and Galvão 2006).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Jurberg and Galvão 2006).
Genus Triatoma Laporte de Castelnau, 1832
Triatomabrasiliensis Neiva, 1911
Geographic distribution. Brazil (Jurberg and Galvão 2006).
Natural hosts. Various mammals. Zoonotic on humans (Jurberg and Galvão 2006).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Jurberg and Galvão 2006).
Triatomadimidiata (Latrielle, 1811)
Geographic distribution. Central and South America (Jurberg and Galvão 2006).
Natural hosts. Various mammals. Zoonotic on humans (Jurberg and Galvão 2006).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Jurberg and Galvão 2006).
Triatomagerstaeckeri (Stål, 1859)
Geographic distribution. Southwestern USA, Mexico (Wozniak et al. 2015).
Natural hosts. Various mammals. Zoonotic on humans (Wozniak et al. 2015).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None (T.gerstaeckeri has been found to be naturally infected with Trypanosomacruzi but its role as a natural vector for human disease is not fully understood) (Reisenman et al. 2010).
Triatomainfestans (Klug in Meyen, 1834)
Geographic distribution. South America (Jurberg and Galvão 2006).
Natural hosts. Various mammals. Zoonotic on humans (Jurberg and Galvão 2006).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Jurberg and Galvão 2006).
Triatomalectularia (Stål, 1859)
Geographic distribution. Southern and southeastern USA, Mexico (Bern et al. 2011).
Natural hosts. Various mammals. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None (T.lectularia has been found to be naturally infected with Trypanosomacruzi but its role as a natural vector for human disease is not fully understood) (Bern et al. 2011).
Triatomaprotracta (Uhler, 1894)
Geographic distribution. Southwestern USA, Mexico (Bern et al. 2011).
Natural hosts. Woodrats (Neotoma). Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None (T.protracta has been found to be naturally infected with Trypanosomacruzi but its role as a natural vector for human disease is not fully understood) (Bern et al. 2011).
Triatomapseudomaculata Correa & Espínola, 1964
Geographic distribution. Brazil (Ribeiro et al. 2019; Soares et al. 2000).
Natural hosts. Various mammals. Zoonotic on humans (Soares et al. 2000).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens.Trypanosomacruzi (Chagas disease, American trypanosomiasis) (Soares et al. 2000; Ribeiro et al. 2019).
Triatomarecurva (Stål, 1868)
Geographic distribution. Southwestern USA, Mexico (Bern et al. 2011).
Natural hosts. Rodents. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None (T.recurva has been found to be naturally infected with Trypanosomacruzi but its role as a natural vector for human disease is not fully understood) (Bern et al. 2011).
Triatomarubida (Uhler, 1894)
Geographic distribution. Southwestern USA, Central America (Bern et al. 2011).
Natural hosts. Rodents. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None (T.rubida has been found to be naturally infected with Trypanosomacruzi but its role as a natural vector for human disease is not fully understood) (Reisenman et al. 2010; Bern et al. 2011).
Triatomarubrofasciata (De Geer, 1773)
Geographic distribution. Eastern North America, Southeast Asia, Pacific Islands (Bern et al. 2011; Huang et al. 2018).
Natural hosts. Rodents. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None; implicated in anaphylactic shock from bites (Huang et al. 2018).
Triatomasanguisuga (LeConte, 1855)
Geographic distribution. Eastern United States (Bern et al. 2011).
Natural hosts. Several groups of mammals, birds, reptiles, and amphibians. Zoonotic on humans (Bern et al. 2011).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Triatomasordida (Stål, 1859)
Geographic distribution. South America (Crocco and Catalá 1997; Ribeiro et al. 2019).
Natural hosts. Various mammals. Zoonotic on humans (Crocco and Catalá 1997).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin
Vectored pathogens.Trypanosomacruzi (Chagas Disease, American trypanosomiasis) (Ribeiro et al. 2019).
●●●●●●●●●●●● Cimicidae Latreille, 1802
Genus Cimex Linnaeus, 1758
Cimexadjunctus Barber, 1939
Geographic distribution. Eastern North America (Goddard 2012).
Natural hosts. Bats. Zoonotic on humans as incidental hosts (Goddard 2012).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Cimexhemipterus (Fabricius, 1802)
Geographic distribution. Circumtropical (Usinger 1966; Mathison and Pritt 2021).
Natural hosts. Humans (Usinger 1966; Mathison and Pritt 2021).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Cimexlectularius Linnaeus, 1758
Geographic distribution. Worldwide (Usinger 1966; Mathison and Pritt 2021).
Natural hosts. Humans (Usinger 1966; Mathison and Pritt 2021).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Cimexpilosellus (Horváth, 1910)
Geographic distribution. Western North America (Goddard 2012).
Natural hosts. Bats. Zoonotic on humans as incidental hosts (Goddard 2012).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Cimexpipistrelli Jenyns, 1839
Geographic distribution. Europe and Central Asia (Goddard 2012).
Natural hosts. Bats. Zoonotic on humans as incidental hosts (Goddard 2012).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Leptocimex Roubaud, 1913
Leptocimexboueti (Brumpt, 1910)
Geographic distribution. Africa (Miller 2008).
Natural hosts. Bats. Zoonotic on humans as incidental hosts (Miller 2008).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Haematosiphon Champion, 1900
Haematosiphoninodora (Dugès, 1892)
Geographic distribution. North and Central America (Mullen and Durden 2019).
Natural hosts. Birds, primarily poultry. Zoonotic on humans as incidental hosts (Mullen and Durden 2019).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Hesperocimex List, 1925
Hesperocimexcoloradensis List, 1925
Geographic distribution. North and Central America (Mullen and Durden 2019).
Natural hosts. Birds. Zoonotic on humans as incidental hosts (Mullen and Durden 2019).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
Genus Oeciacus Stål, 1873
Oeciacusvicarius Horváth, 1912
Geographic distribution. North America (Mullen and Durden 2019).
Natural hosts. Birds, primarily chimney swifts (Chaetura). Zoonotic on humans as incidental hosts (Mullen and Durden 2019).
Route of infection. Exposure to nymphs and adults in the environment.
Site in human host. Skin.
Vectored pathogens. None.
●●●●●●●●●●● Psocodea Hennig, 1966
Anoplura Leach, 1815
Phthiraptera Haeckel, 1896
●●●●●●●●●●●● Pediculidae Leach, 1817
Genus Pediculus Linnaeus, 1758
Pediculushumanuscapitis De Geer, 1778
Geographic distribution. Worldwide (Veracx and Raoult 2012; Meister and Ochsendorf 2016).
Natural hosts. Humans (Veracx and Raoult 2012; Bonilla et al. 2013).
Route of infection. Direct person-to-person contact, contaminated fomites (Veracx and Raoult 2012; Bonilla et al. 2013).
Site in human host. Hair shafts, commonly on the scalp (Veracx and Raoult 2012; Bonilla et al. 2013; Meister and Ochsendorf 2016).
Vectored pathogens. None.
Pediculushumanushumanus Linnaeus, 1758
Pediculuscorporis De Geer, 1778
Geographic distribution. Worldwide (Veracx and Raoult 2012).
Natural hosts. Humans (Veracx and Raoult 2012; Bonilla et al. 2013).
Route of infection. Direct person-to-person contact, contaminated fomites (Bonilla et al. 2013; Veracx and Raoult 2012).
Site in human host. Skin; P.h.humanus primarily lives off the human host and only migrates over to feed (Bonilla et al. 2013).
Vectored pathogens.Rickettsiaprowazekii (epidemic typhus), Bartonellaquintana (trench fever), Borreliarecurrentis (louse-borne relapsing fever) (Bonilla et al. 2013).
●●●●●●●●●●●● Pthiridae Ewing, 1929
Genus Pthirus Leach, 1815
Phthirus, misspelling
Pthiruspubis (Linnaeus, 1758)
Geographic distribution. Worldwide (Anderson and Chaney 2009).
Natural hosts. Humans (Anderson and Chaney 2009).
Route of infection. Direct person-to-person contact (Anderson and Chaney 2009).
Site in human host. Hair shafts, usually coarse hair (pubic hair, eyebrows, eye lashes, facial hair) (Anderson and Chaney 2009).
Vectored pathogens. None.
●●●●●●●●●●● Coleoptera Linnaeus, 1758
●●●●●●●●●●●● Ptinidae Latreille, 1802
Genus Stegobium Motschulsky, 1860
Stegobiumpaniceum (Linnaeus, 1758)
Geographic distribution. Worldwide (Bousquet 1990).
Natural hosts. None; causes facultative canthariasis (infestation with beetles) in humans (Smadi et al. 2014).
Route of infection. Contamination from the environment (Smadi et al. 2014).
Site in human host. Skin (Smadi et al. 2014).
Vectored pathogens. None.
Notes. This species was reported from the skin of a patient with lupus after treatment for facultative myiasis caused by Luciliasericata (Smadi et al. 2014). This appears to represent facultative canthariasis, with the beetles feeding on dead and/or dried skin.
Genus Trogoderma Dejean, 1821
Geographic distribution. Worldwide (Bousquet 1990).
Natural hosts. None; causes facultative canthariasis in humans (Smadi et al. 2014).
Route of infection. Contamination from the environment (Smadi et al. 2014).
Site in human host. Skin (Smadi et al. 2014).
Vectored pathogens. None
Notes. A member of this genus was reported from the skin of a patient with lupus after treatment for facultative myiasis caused by Luciliasericata (Smadi et al. 2014). This appears to represent facultative canthariasis, with the beetles feeding on dead and/or dried skin.
●●●●●●●●●●●● Tenebrionidae Latreille, 1802
Genus Tenebrio Linnaeus, 1758
Tenebriomolitor Linnaeus, 1758
Geographic distribution. Worldwide (Bousquet 1990).
Natural hosts. None; causes facultative canthariasis in humans (Rodriguez-Morales 2018).
Route of infection. Contamination from the environment (Rodriguez-Morales 2018).
Site in human host. Skin ulcer (Rodriguez-Morales 2018).
Vectored pathogens. None.
Notes.Tenebriomolitor is a cosmopolitan pest of stored grains and other foodstuffs. A larva of T.molitor was discovered in a skin ulcer of an AIDS patient in rural Colombia (Rodriguez-Morales 2018). This case represents facultative canthariasis. Previous reports of T.molitor from the human intestinal tract (Palmer 1946) or urinary tract (Aelami et al. 2019) probably represents spurious passage, environmental contamination, or urethral sounding.
●●●●●●●●●●● Siphonaptera Latreille, 1824
●●●●●●●●●●●● Heteropsyllidae Baker, 1904
Genus Tunga Jarocki, 1838
Tungapenetrans (Linnaeus, 1758)
Geographic distribution. Central and South America, Caribbean, Africa, Madagascar, Central Asia (Feldmeier et al. 2014).
Natural hosts. Many mammals. Zoonotic on humans (Feldmeier et al. 2014).
Route of infection. Contact with contaminated soil (e.g., walking barefoot) (Feldmeier et al. 2014).
Site in human host. Subcutaneous, especially on the bottom of feet and between toes (Feldmeier et al. 2014).
Vectored pathogens. None.
Tungatrimamillata Pampiglione et al., 2002
Geographic distribution. South America (Peru, Bolivia, Brazil) (Feldmeier et al. 2014).
Natural hosts. Mammals, primarily goats, cattle, pigs. Zoonotic on humans (Feldmeier et al. 2014).
Route of infection. Contact with contaminated soil (e.g., walking barefoot) (Feldmeier et al. 2014).
Site in human host. Subcutaneous, especially on the bottom of feet and between toes (Feldmeier et al. 2014).
Vectored pathogens. None.
●●●●●●●●●●●● Ceratophyllidae Dampf, 1908
Genus Nodopsyllus Jordan, 1933
Nodopsyllusfasciatus (Bosc, 1800)
Geographic distribution. Worldwide (Bitam et al. 2010).
Natural hosts. Rodents. Zoonotic on humans (Bitam et al. 2010).
Route of infection. Exposure to adults in the environment.
Site in human host. Skin.
Vectored pathogens.Hymenolepisnana (dwarf tapeworm disease), H.diminuta (rate tapeworm disease), Yersiniapestis (plague) (Bitam et al. 2010).
Genus Oropsylla Wagner & Ioff, 1926
Oropsyllamontana (Baker, 1895)
Geographic distribution. Western North America (Hinnebusch et al. 2017).
Natural hosts. Rodents, primarily prairie dogs and ground squirrels. Zoonotic on humans (Hinnebusch et al. 2017).
Route of infection. Exposure to adults in the environment.
Site in human host. Skin.
Vectored pathogens.Yersiniapestis (plague) (Hinnebusch et al. 2017).
●●●●●●●●●●●● Pulicidae Billberg, 1820
Genus Ctenocephalides Stiles & Collins, 1930
Ctenocephalidescanis (Curtis, 1826)
Geographic distribution. Worldwide (Mathison and Pritt 2014).
Natural hosts. Wild and domestic canids and felids. Zoonotic on humans (Mathison and Pritt 2014).
Route of infection. Exposure to adults in the environment.
Site in human host. skin.
Vectored pathogens.Dipylidiumcaninum (dog tapeworm disease), Hymenolepisnana (dwarf tapeworm disease), H.diminuta (rat tapeworm disease) (Mathison and Pritt 2014).
Ctenocephalidesfelis (Bouché, 1835)
Geographic distribution. Worldwide (Mathison and Pritt 2014).
Natural hosts. Wild and domestic canids and felids. Zoonotic on humans (Mathison and Pritt 2014).
Route of infection. Exposure to adults in the environment.
Site in human host. skin.
Vectored pathogens.Dipylidiumcaninum (dog tapeworm disease), Hymenolepisnana (dwarf tapeworm disease), H.diminuta (rate tapeworm disease), Bartonellahenselae (cat-scratch disease), Rickettsiafelis (feline rickettsiae), Acanthocheilonemareconditum (ocular filariasis) (Orihel and Eberhard 1998; Mathison and Pritt 2014).
Genus Echidnophaga Olliff, 1886
Echidnophagagallinacea (Westwood, 1875)
Geographic distribution. Worldwide (Carlson and Fox 2009).
Natural hosts. Many birds and mammals. Zoonotic on humans (Carlson and Fox 2009).
Route of infection. Exposure to adults in the environment; exposure to infected birds (Carlson and Fox 2009).
Site in human host. Skin.
Vectored pathogens. None.
Genus Synopsyllus Wagner & Roubaud, 1932
Synopsyllusfonquerniei Wagner & Roubaud, 1932
Geographic distribution. Madagascar (Kreppel et al. 2016).
Natural hosts. Rats. Zoonotic on humans (Kreppel et al. 2016).
Route of infection. Exposure to adults in the environment.
Site in human host. Skin.
Vectored pathogens.Yersiniapestis (plague) (Kreppel et al. 2016).
Genus Pulex Linnaeus, 1758
Pulexirritans Linnaeus, 1758
Geographic distribution. Worldwide (Mathison and Pritt 2014).
Natural hosts. Many mammals, including humans (Mathison and Pritt 2014).
Route of infection. Exposure to adults in the environment.
Site in human host. Skin.
Vectored pathogens.Dipylidiumcaninum (dog tapeworm disease), Hymenolepisnana (dwarf tapeworm disease), H.diminuta (rate tapeworm disease) (Mathison and Pritt 2014).
Genus Xenopsylla Glinkiewicz, 1907
Xenopsyllabrasiliensis (Baker, 1904)
Geographic distribution. Africa, South America, India (Miarinjara et al. 2016; Mohammadi et al. 2021).
Natural hosts. Rats. Zoonotic on humans (Miarinjara et al. 2016; Mohammadi et al. 2021).
Route of infection. Exposure to adults in the environment.
Site in human host: Skin.
Vectored pathogens. Yersiniapestis (plague) (Miarinjara et al. 2016; Mohammadi et al. 2021).
Xenopsyllacheopis (Rothschild, 1903)
Geographic distribution. Worldwide (Perry and Fetherston 1997).
Natural hosts. Mammals, primarily rodents (rats). Zoonotic on humans (Perry and Fetherston 1997).
Route of infection. Exposure to adults in the environment.
Site in human host. Skin.
Vectored pathogens.Yersiniapestis (plague), Rickettsiatyphi (murine (epidemic) typhus) (Mathison and Pritt 2014; Perry and Fetherston 1997).
●●●●●●●●●●● Diptera Linnaeus, 1758
●●●●●●●●●●●● Phoridae Curtis, 1833
Genus Megaselia Róndani, 1856
Megaseliascalaris Loew, 1866
Geographic distribution. Worldwide (Disney 2008).
Natural hosts. None, agent of facultative and incidental myiasis in humans (Disney 2008).
Route of infection. Oviposition on pre-existing wounds (Disney 2008).
Site in human host. Soft tissues, pre-existing wounds (Hira et al. 2004; Disney 2008).
Notes. Although this species is known to cause facultative myiasis is pre-existing wounds of soft tissues and the upper respiratory tract (Hira et al. 2004; Disney 2008), reports from urine (Ghavami and Djalilvand 2015) should be met with caution.
●●●●●●●●●●●● Muscidae Latreille, 1802
Genus Musca Linnaeus, 1758
Muscadomestica Linnaeus, 1758
Muscanebulo Fabricius, 1794
Muscahottentota Robineau-Desvoidy, 1830
Muscafrontalis Macquart, 1843
Muscasenegalensis Macquart, 1843
Muscasantae-helenae Macquart, 1848
Muscagymnosomea Róndani, 1862
Muscaniveisquama Thomson, 1869
Muscacurviforceps Saccà & Rivosechi, 1956
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None, agent of facultative and incidental myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
●●●●●●●●●●●● Fanniidae Schnabl & Dziedzicki, 1911
Genus Fannia Robineau-Desvoidy, 1830
Fanniacanicularis (Linnaeus, 1761)
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None, agent of facultative and incidental myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
●●●●●●●●●●●● Calliphoridae Brauer & Bergenstamm, 1889
Genus Auchmeromyia Brauer & Bergenstamm, 1891
Auchmeromyiasenegalensis Macquart, 1851
Geographic distribution. Sub-Saharan Africa, Cape Verde Islands (Francesconi and Lupi 2012).
Natural hosts. Several mammals, including humans (Francesconi and Lupi 2012).
Route of infection. Exposure to larvae in the environment (Francesconi and Lupi 2012).
Site in human host. Skin (sanguinivorous) (Francesconi and Lupi 2012).
Genus Calliphora Robineau-Desvoidy, 1820
Calliphorahilli Patton, 1925
Geographic distribution. Australia (Francesconi and Lupi 2012).
Natural hosts. None; causes facultative myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Eye (Francesconi and Lupi 2012).
Calliphoravicina Robineau-Desvoidy, 1830
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None; causes facultative myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Genus Cochliomyia Townsend, 1915
Cochliomyiahominovorax (Coquerel, 1858)
Geographic distribution. Central and South America, Caribbean (Scott et al. 2017; Parker et al. 2020).
Natural hosts. Most mammals, including humans (Scott et al. 2017; Parker et al. 2020).
Route of infection. Oviposition on pre-existing wounds, ears, nose, oral cavity (Francesconi and Lupi 2012).
Site in human hose. Skin, soft tissues, pre-existing wounds, ears, nose, oral cavity (Francesconi and Lupi 2012).
Genus Chrysomya Robineau-Desvoidy, 1830
Chrysomyaalbiceps (Wiedemann, 1819)
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None; causes facultative myiasis in humans and sheep (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Chrysomyabezziana (Villeneuve, 1914)
Geographic distribution. India, Arabian Peninsula, Indonesia, Philippines, New Guinea (Francesconi and Lupi 2012).
Natural hosts. Sheep. Zoonotic on humans as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Chrysomyamegacephala (Fabricius, 1794)
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None; causes facultative myiasis in humans and other mammals (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Chrysomyarufifacies (Macquart, 1842)
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. None; causes facultative myiasis in humans and other mammals (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Genus Cordylobia Gruenberg, 1903
Cordylobiaanthropophaga Blanchard, 1872
Geographic distribution. East, Central, and West Africa (Francesconi and Lupi 2012).
Natural hosts. Mammals, including rodents, monkeys, ruminants, and humans (Francesconi and Lupi 2012).
Route of infection. Exposure to first-instar larvae on fomites (soil, air-drying laundry) (Francesconi and Lupi 2012).
Site in human host. Skin (Francesconi and Lupi 2012).
Cordylobiarodhaini Gedoelst, 1910
Geographic distribution. Tropical Africa (Pezzi et al. 2015).
Natural hosts. Mammals, primarily rodents. Zoonotic on humans (Pezzi et al. 2015).
Route of infection. Exposure to larvae on fomites (soil, air-drying laundry) (Pezzi et al. 2015).
Site in human host. Skin (Pezzi et al. 2015).
Genus Lucilia Robineau-Desvoidy, 1830
Luciliacuprina (Wiedemann, 1830)
Geographic distribution. Nearly worldwide, more common in warm climates (Francesconi and Lupi 2012).
Natural hosts. None, causes facultative myiasis in sheep and humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Luciliasericata (Meigan, 1826)
Geographic distribution. Europe, North, Central, and South America (Francesconi and Lupi 2012).
Natural hosts. None, causes facultative myiasis in sheep and humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Vectored pathogens.Wohlfahrtiimonaschitiniclastica, Ignatzschineriaindica (Lysaght et al. 2018).
Genus Phormia Robineau-Desvoidy, 1830
Phormiaregina (Meigen, 1826)
Geographic distribution. Northern Hemisphere (Francesconi and Lupi 2012).
Natural hosts. None, causes facultative myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Genus Protophormia Townsend, 1908
Protophormiaterraenovae Robineau-Desvoidy, 1830
Geographic distribution. Northern Hemisphere (Francesconi and Lupi 2012).
Natural hosts. None, causes facultative myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
●●●●●●●●●●●● Sarcophagidae Macquart, 1834
Genus Peckia Robineau-Desvoidy, 1830
Peckialambens (Wiedemann, 1830)
Geographic distribution. Central and South America, Caribbean (Fernandes et al. 2009).
Natural hosts. None; cause facultative myiasis in humans (Fernandes et al. 2009).
Route of infection. Oviposition on pre-existing wounds (Fernandes et al. 2009).
Site in human host. Skin and soft tissues (Fernandes et al. 2009).
Genus Sarcophaga Meigen, 1826
Sarcophagadux Thomson, 1869
Geographic distribution. Worldwide (Sukontason et al. 2014).
Natural hosts. None, causes facultative myiasis in humans (Sukontason et al. 2014).
Route of infection. Oviposition on pre-existing wounds, ear (Sukontason et al. 2014).
Site in human host. Ear, skin and soft tissues (Chaiwong et al. 2014; Sukontason et al. 2014).
Sarcophagaperegrina (Robineau-Desvoidy, 1830)
Sarcophagafucicauda Böttcher, 1912
Sarcophagahutsoni Parker, 1923
Sarcophagameriana Zumpt, 1951
Geographic distribution. Asia, Africa, Australia, New Zealand (Kim et al. 2018).
Natural hosts. None, causes facultative myiasis in humans (Kim et al. 2018).
Route of infection. Oviposition on pre-existing wounds, ear, eye (Chigusa et al. 2000; Miura et al. 2005).
Site in human host. Nose, oral cavity, eye (Chigusa et al. 2005; Miura et al. 2005).
Sarcophagapernix Harris, 1789
Muscahaemorrhoidalis Fallén, 1817
Geographic distribution. Europe, Asia, North Africa (Francesconi and Lupi 2012).
Natural hosts. None, causes facultative myiasis in humans (Francesconi and Lupi 2012).
Route of infection. Oviposition on pre-existing wounds, ear (Braverman et al. 1994).
Site in human host. Ear, skin and soft tissues (Braverman et al. 1994).
Sarcophagaruficornis (Fabricius, 1794)
Geographic distribution. Worldwide (Suwannayod et al. 2013).
Natural hosts. None, causes facultative myiasis in humans (Suwannayod et al. 2013).
Route of infection. Oviposition on pre-existing wounds (Suwannayod et al. 2013).
Site in human host. Skin and soft tissues (Suwannayod et al. 2013).
Sarcophagaseptentrionalis (Rohdendorf, 1937)
Geographic distribution. East Asia (Chigusa et al. 2006).
Natural hosts. None; causes facultative myiasis in humans (Chigusa et al. 2006)
Route of infection. Oviposition on pre-existing wounds (Chigusa et al. 2006).
Site in human host. Oral cavity (Chigusa et al. 2006).
Genus Wohlfahrtia Brauer & von Bergenstamm, 1889
Wohlfahrtiamagnifica (Schiner, 1861)
Geographic distribution. Mediterranean Europe, North Africa, Central and Southeast Asia, Russia (Francesconi and Lupi 2012).
Natural hosts. Mammals and birds, including sheep, cattle, poultry, and humans (Francesconi and Lupi 2012).
Route of infection. Larviposition on wounds, tissues (Francesconi and Lupi 2012).
Site in human host. Skin, soft tissues, pre-existing wounds, oral cavity, ears (Francesconi and Lupi 2012).
Vectored pathogens.Wohlfahrtiimonaschitiniclastica, Ignatzschineriaindica (Barker et al. 2014).
Wohlfahrtiaopaca (Coquillett, 1897)
Geographic distribution. Western North America (Francesconi and Lupi 2012).
Natural hosts. Wild and domestic canids and felids, rabbits, mustelids. Zoonotic in human as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Larviposition on wounds, tissues (Francesconi and Lupi 2012).
Site in human host. Skin and soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
Wohlfahrtiavigil (Walker, 1849)
Geographic distribution. Eastern North America, southern Europe, Russia, Pakistan (Francesconi and Lupi 2012).
Natural hosts. Wild and domestic canids and felids, rabbits, mustelids. Zoonotic in human as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Larviposition on wounds, tissues (Francesconi and Lupi 2012).
Site in human host. Skin and soft tissues, pre-existing wounds (Francesconi and Lupi 2012).
●●●●●●●●●●●● Oestridae Leach, 1815
Genus Alouattamyia Townsend, 1931
Allouattamyiabaeri (Shannon & Green, 1926)
Geographic distribution. South America (Francesconi and Lupi 2012).
Natural hosts. Non-human primates. Zoonotic in human as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Exposure to first-instar larvae in the environment (Francesconi and Lupi 2012).
Site in human host. Upper respiratory tract (Francesconi and Lupi 2012).
Genus Dermatobia Brauer, 1860
Dermatobiahominis (Linnaeus in Pallas, 1781)
Geographic distribution. Central and South America, Caribbean (Francesconi and Lupi 2012).
Natural hosts. Many mammals, including humans, and birds; vectored by mosquitoes and ticks (Francesconi and Lupi 2012).
Route of infection. Bite of a mosquito or tick, the phoretic host for D.hominis eggs (Francesconi and Lupi 2012).
Site in human host. Skin (Francesconi and Lupi 2012).
Genus Cuterebra Clark, 1815
Geographic distribution. North and Central America (Francesconi and Lupi 2012).
Natural hosts. Rodents and lagomorphs; cats and other mammals can serve as reservoir hosts. Zoonotic in human as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Exposure to first-instar larvae in contaminated soil, litter, etc.
Site in human host. Skin (second-instar, third-instar larvae), viscera and lungs (third-instar larvae) (Cornet et al. 2003; Delshad et al. 2008; Francesconi and Lupi 2012; Hale et al. 2019).
Notes. Cases of human infestation with Cuterebra are usually not identified to the species level.
Genus Gasterophilus Leach, 1817
Geographic distribution. Worldwide (Zumpt 1965; Francesconi and Lupi 2012).
Natural hosts. Horses, zebras, elephants, rhinoceroses. Zoonotic in human as incidental hosts (Zumpt 1965; Francesconi and Lupi 2012).
Route of infection. Oviposition on skin and mucus membranes (Francesconi and Lupi 2012).
Site in human host. Skin, eye, oral cavity (Francesconi and Lupi 2012).
Notes. Cases of human infestation with Gasterophilus are usually not identified to the species level.
Genus Hypoderma Latreille, 1818
Hypodermabovis (Linnaeus, 1758)
Geographic distribution. North America, Europe, Asia, Africa (Zumpt 1965; Francesconi and Lupi 2012).
Natural hosts. Wild and domestic ruminants. Zoonotic in human as incidental hosts (Zumpt 1965; Francesconi and Lupi 2012).
Route of infection. Oviposition on hair or skin, or possibly direct contact with first-instar larvae on infected animals (Francesconi and Lupi 2012).
Site in human host. Skin (Francesconi and Lupi 2012).
Hypodermalineatum (Viller, 1789)
Geographic distribution. North America, Europe, Asia, Africa (Zumpt 1965; Francesconi and Lupi 2012).
Natural hosts. Wild and domestic ruminants. Zoonotic in human as incidental hosts (Zumpt 1965; Francesconi and Lupi 2012).
Route of infection. Oviposition on hair or skin, or possibly direct contact with first-instar larvae on infected animals (Francesconi and Lupi 2012)
Site in human host. Skin (Francesconi and Lupi 2012).
Hypodermatarandi (Linnaeus, 1758)
Geographic distribution. Northern North America, Northern Eurasia (Zumpt 1965; Francesconi and Lupi 2012).
Natural hosts. Caribou. Zoonotic in human as incidental hosts (Zumpt 1965; Francesconi and Lupi 2012).
Route of infection. Oviposition on hair, skin, or mucus membranes, or possibly direct contact with first-instar larvae on infected animals (Francesconi and Lupi 2012).
Site in human host. Skin, eyes, oral cavity (Francesconi and Lupi 2012).
Genus Oestrus Linnaeus, 1758
Oestrusovis Linnaeus, 1758
Geographic distribution. Worldwide (Francesconi and Lupi 2012).
Natural hosts. Sheep, goats, other ruminants. Zoonotic in human as incidental hosts (Francesconi and Lupi 2012).
Route of infection. Larviposition on eyes and mucus membranes (Francesconi and Lupi 2012).
Site in human host. Eye, throat (Francesconi and Lupi 2012).
●●●●● Nematoda Diesking, 1861
●●●●●● Dorylaimia Inglis, 1983
●●●●●●● Dioctophymatida Baylis & Daubney, 1926
●●●●●●●● Dioctophymidae Railliet, 1915
Genus Dioctoyphyme Collet-Meygret, 1802
Dioctophyma, misspelling
Dioctophymerenale (Goeze, 1782)
Geographic distribution. Worldwide (Angelou et al. 2020)
Natural hosts. First intermediate hosts are annelids. Second intermediate and paratenic hosts are primarily freshwater fish and amphibians. Definitive hosts are carnivores, including mustelids and canids. Zoonotic in humans, harboring L3 larvae or adults (Angelou et al. 2020).
Route of infection. Ingestion of L3 larvae in undercooked paratenic hosts (Orihel and Ash 1995).
Site in human host. Subcutaneous (L3 larvae), kidneys (adults) (Orihel and Ash 1995).
Genus Eustrongylides Jägerskiöld, 1909
Geographic distribution. Worldwide (Anderson 2000).
Natural hosts. First intermediate hosts are aquatic annelids. The second intermediate hosts are fish; fish, amphibians, and reptiles can serve as paratenic hosts. Definitive hosts are birds. Zoonotic in humans as dead-end hosts harboring L3 or L4 larvae (Anderson 2000).
Route of Infection. Ingestion of L3 or precocious L4 larvae in infected intermediate or paratenic hosts (Anderson 2000).
Site in human host. Skin, Abdominal and peritoneal cavities, possible ectopic migration to other parts of the body (Orihel and Ash 1995; Eberhard and Ruiz-Tiben 2014).
Notes. There about 20 described species of Eustrongylides. Human cases with larval Eustrongylides have been reported from North America and East Africa and have not been characterized at the species level.
●●●●●●● Trichinellida Hall, 1916
Trichocephalida Spasski, 1954
●●●●●●●● Anatrichosomatidae Yamaguti, 1961
Genus Anatrichosoma Smith & Chitwood, 1954
Geographic distribution. Worldwide (Eberhard et al. 2010, 2014a).
Natural hosts. The life cycle is not completely understood, and it is not known if there are more than one host. Definitive hosts include non-human primates, tree shrews, rodents, marsupials. Zoonotic in humans as incidental hosts (Eberhard et al. 2010, 2014a).
Route of infection. Unknown, possible ingestion of embryonated eggs or unknown intermediate host (Eberhard et al. 2010, 2014a).
Site in human host. Skin and soft tissues, oral mucosa (Eberhard et al. 2010, 2014a).
Notes. Human cases of anatrichosomiasis have been diagnosed by histopathology. Because Anatrichosoma spp. have not been described morphologically by histopathology, it is not currently possible to characterize human isolates at the species level. Given the morphology and epidemiology, cases from the human oral cavity from Mexico and the United States are probably attributable to A.buccalis Pence & Little, 1972 (Eberhard et al. 2010, 2014a).
●●●●●●●● Capillariidae Railliet, 1915
Genus Calodium Dujardin, 1845
Calodiumhepaticum (Bancroft, 1893)
Geographic distribution. Worldwide (Li et al. 2010).
Natural hosts. Rodents. Zoonotic in humans as incidental hosts (Li et al. 2010).
Route of infection. Ingestion of embryonated eggs on soil-contaminated fomites (Li et al. 2010).
Site in human host. Liver (Li et al. 2010).
Notes. Eggs of C.hepaticum detected in human stool probably represent spurious passage and not true infection.
Genus Eucoleus Dujardin, 1845
Eucoleusaerophilus (Creplin, 1839)
Geographic distribution. Worldwide (Traversa et al. 2011).
Natural hosts. Paratenic hosts are earthworms. Definitive hosts are carnivores. Zoonotic in humans as incidental hosts (Traversa et al. 2011).
Route of infection. Ingestion of embryonated eggs or paratenic hosts (Traversa et al. 2011).
Site in human host. Lungs (Traversa et al. 2011).
Genus Paracapillaria Chitwood et al., 1968
Paracapillariaphilippinensis (Velasquez et al., 1968)
Geographic distribution. Southeast Asia, Philippines, Egypt, South America (Cross 1992; Attia et al. 2012; Eiras et al. 2018).
Natural hosts. Intermediate hosts are freshwater fish. Definitive hosts are humans, fish-eating birds (Cross 1992).
Route of infection. Ingestion of L1 larvae in infected intermediate host (Cross 1992).
Site in human host. Small intestine (Cross 1992).
●●●●●●●● Trichinellidae Ward, 1907
Genus Trichinella Railliet, 1895
Trichinellabritovi Pozio et al., 1992
Trichinella strain T3
Geographic distribution. Europe, North America, Asia, West Africa (Gottstein et al. 2009).
Natural hosts. Mammals. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are wild and domestic pigs, horses, foxes, jackals (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellamurelli Pozio & La Rosa, 2000
Trichinella strain T5
Geographic distribution. North America (Gottstein et al. 2009; Hall et al. 2012).
Natural hosts. Mammals, primarily carnivores. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human are bears and horses (Gottstein et al. 2009; Hall et al. 2012).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellanativa Britov & Boev, 1972
Trichinella strain T2
Geographic distribution. Circumboreal (Gottstein et al. 2009).
Natural hosts. Mammals, primarily carnivores. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are bears and walrus (Gottstein et al. 2009; Springer et al. 2017).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellanelsoni Britov & Boev, 1972
Trichinella strain T7
Geographic distribution. Europe, North America, Asia, West Africa (Gottstein et al. 2009).
Natural hosts. Mammals. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are wild and domestic pigs, horses, foxes, jackals (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellapapuae Pozio et al., 1999
Geographic distribution. Papua New Guinea, Thailand (Gottstein et al. 2009).
Natural hosts. Mammals (primarily pigs), saltwater crocodiles. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are wild and domestic pigs (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellapseudospiralis Garkavi, 1972
Trichinella strain T4
Geographic distribution. Worldwide (Gottstein et al. 2009).
Natural hosts. Mammals and birds. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are wild and domestic pigs (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinellaspiralis (Owen, 1835)
Trichinella strain T1
Geographic distribution. Worldwide (Gottstein et al. 2009).
Natural hosts. Mammals. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are wild and domestic pigs (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
Trichinella Strain T6
Geographic distribution. Northern and montane North America (Gottstein et al. 2009).
Natural hosts. Mammals, primarily carnivores. Zoonotic in humans (Gottstein et al. 2009).
Route of infection. Ingestion of L1 larvae in infected hosts; common sources of human infection are bears, wild felids (Gottstein et al. 2009).
Site in human host. Small intestine (adults), skeletal muscle (L1 larvae) (Gottstein et al. 2009).
●●●●●●● Muspiceida Bain & Chabaud, 1959
●●●●●●●● Robertdollfusidae Chabaud & Campana, 1950
Genus Haycocknema Spratt et al., 1999
Haycocknemaperplexum Spratt et al., 1999
Geographic distribution. Australia (McKelvie et al. 2013; Vos et al. 2016).
Natural hosts. Unknown, presumed zoonotic in humans (McKelvie et al. 2013; Vos et al. 2016).
Route of infection. Unknown, presumed ingestion of larvae in natural hosts (McKelvie et al. 2013; Vos et al. 2016).
Site in human host. Skeletal muscle (McKelvie et al. 2013; Vos et al. 2016).
●●●●●●●● Trichuridae Ransom, 1911
Genus Trichuris Roederer, 1761
Trichuristrichiura (Linnaeus, 1771)
Geographic distribution. Worldwide (Betson et al. 2015).
Natural hosts. Humans (Betson et al. 2015).
Route of infection. Ingestion of embryonated eggs in fecally contaminated food, water, fomites (Betson et al. 2015).
Site in human host. Large intestine (Betson et al. 2015).
Notes. The zoonotic potential of T.trichiura is not well understood and is unclear whether there are multiple species infecting humans or whether other animals can harbor T.trichiura and serve as reservoir hosts for human infection (Betson et al. 2015).
Trichurisvulpis Froelich, 1789
Geographic distribution. Worldwide (Dunn et al. 2002).
Natural hosts. Wild and domestic canids. Zoonotic in humans (Dunn et al. 2002).
Route of infection. Ingestion of embryonated eggs (Dunn et al. 2002).
Site in human host. Large intestine (Dunn et al. 2002).
Notes. Fully-embryonated eggs of T.vulpis in human stool specimens may also represent spurious passage and not true infection.
●●●●●● Chromadoria Inglis, 1983
●●●●●●● Spururina Railliet & Henry, 1915
●●●●●●●● Ascaridida DeLay & Blaxter, 2002
●●●●●●●●● Anisakidae Skrjabin & Karokhin, 1945
Genus Anisakis Dujardin, 1845
Geographic distribution. Worldwide; human infection more common in coastal areas (Audicana and Kennedy 2008; Mathison and da Silva 2018).
Natural hosts. First intermediate hosts are marine microcrustaceans. Paratenic hosts are marine fish and squid. Definitive hosts are fish-eating mammals, primarily cetaceans and pinnipeds. Zoonotic in humans as dead-end hosts harboring L3 larvae (Audicana and Kennedy 2008; Mathison and da Silva 2018).
Route of infection. Ingestion of L3 larvae in infected paratenic hosts (Audicana and Kennedy 2008; Mathison and da Silva 2018).
Site in human host. Stomach, esophagus, oral cavity, large intestine; ectopic colonization of peritoneal cavity, mesenteries, omentum, mesocolic lymph nodes, spleen, pleural cavity, and parametrium (Audicana and Kennedy 2008; Mathison and da Silva 2018).
Notes. While most human cases have been attributed to members of A.simplex sensu lato (including A.simplex (Rudolphi, 1809), A.pegreffii (Campana-Rouget & Biocca, 1955), and A.berlandi Mattiucci et al. 2014) or A.physeteris (Baylis, 1923), reliable identification human isolates at the species level is difficult and seldom performed due to a lack of species-level morphologic features of the L3 larvae (the stage found in human host) and the lack of a reliable sequencing library for molecular analysis (Umehara et al. 2007).
Genus Contracaecum Railliet & Henry, 1912
Geographic distribution. Worldwide; human infection more common on coastal areas (Mathison and da Silva 2018).
Natural hosts. First intermediate hosts are marine microcrustaceans. Paratenic hosts are marine fish and squid. Definitive hosts are fish-eating mammals, primarily cetaceans and pinnipeds, and birds. Zoonotic in humans as dead-end hosts harboring L3 larvae (Mathison and da Silva 2018).
Route of infection. Ingestion of L3 larvae in infected paratenic hosts (Mathison and da Silva 2018).
Site in human host. Stomach, esophagus, oral cavity, large intestine; ectopic colonization of various organs possible (Mathison and da Silva 2018).
Notes. It is not currently possible to reliably identify human isolates of Contracaecum at the species level due to a lack of species-level morphologic features of the L3 larvae (the stage found in human host) and the lack of a reliable sequencing library for molecular analysis.
Genus Pseudoterranova Mozgovoi, 1951
Phocanema Myers, 1959
Geographic distribution. Worldwide; human infection more common on coastal areas (Mathison and da Silva 2018).
Natural hosts. First intermediate hosts are marine microcrustaceans. Paratenic hosts are marine fish and squid. Definitive hosts are fish-eating mammals, primarily cetaceans and pinnipeds. Zoonotic in humans as dead-end hosts harboring L3 larvae (Mathison and da Silva 2018).
Route of infection. Ingestion of L3 larvae in infected paratenic hosts (Mathison and da Silva 2018).
Site in human host. Stomach, esophagus, oral cavity, large intestine; ectopic colonization of peritoneal cavity, mesenteries, omentum, mesocolic lymph nodes, spleen, pleural cavity, and parametrium (Mathison and da Silva 2018).
Notes. While many human cases have been attributed to the P.decepiens (Krabbe, 1878) complex, reliable identification human isolates at the species level is difficult and seldom performed due to a lack of species-level morphologic features of the L3 larvae (the stage found in human host) and the lack of a reliable sequencing library for molecular analysis.
●●●●●●●●● Ascarididae Baird, 1853
Genus Ascaris Linnaeus, 1758
Ascarislumbricoides Linnaeus, 1758
Ascarissuum (Goeze, 1782)
Geographic distribution. Worldwide (Betson et al. 2014).
Natural hosts. Pigs. Zoonotic in humans (Betson et al. 2014).
Route of infection. Ingestion of embryonated eggs in fecally contaminated food, water, fomites (Betson et al. 2014).
Site in human host. Lungs (L3 larvae); Small intestine (adults), with ectopic colonization of liver, spleen, gall bladder (Betson et al. 2014).
Notes. The relationship between A.lumbricoides and A.suum is unresolved. While there are genetic differences among Ascaris isolates throughout the world, it is unclear whether such differences represent more than one species with a common ancestor, multiple colonization events between pigs and humans in different geographical areas, or there is one species with geographic variations (Betson et al. 2014). We are maintaining a conservative approach in keeping A.suum in synonymy with A.lumbricoides, based on ecological, biological, morphological, and molecular data (Leles et al. 2012; Liu et al. 2012).
Genus Baylisascaris Sprent, 1968
Baylisascarisprocyonis (Stefanski & Zarnowski, 1951)
Geographic distribution. North and Central America, introduced to Europe and Asia (Gavin et al. 2005).
Natural hosts. Raccoons and other procyonids; dogs can serve as reservoir hosts. Zoonotic in humans as dead-end hosts harboring L3 larvae (Gavin et al. 2005).
Route of infection. Ingestion of embryonated eggs in food, water, fomites contaminated with raccoon feces; possibly also ingestion of paratenic hosts (Gavin et al. 2005).
Site in human host. Brain, eye, liver, lungs (Gavin et al. 2005).
Genus Lagochilascaris Leiper, 1909
Lagochilascarisminor Leiper, 1909
Geographic distribution. Central and South America (Campos et al. 2017).
Natural hosts. Unknown. It has been prosed rodents are intermediate hosts and carnivores are definitive hosts, with humans serving as incidental definitive hosts (Campos et al. 2017).
Route of infection. Unknown, presumed to be ingestion of larvae in infected intermediate or paratenic hosts, possibly ingestion of embryonated eggs (Campos et al. 2017).
Site in human host. Disseminated infection; common sites of infection are subcutaneous, ear, tonsils, nasal sinuses, and mastoid (Campos et al. 2017).
Genus Toxocara Stiles, 1905
Toxocaracanis (Werner, 1792)
Geographic distribution. Worldwide (Despommier 2003).
Natural hosts. Wild and domestic canids. Zoonotic in humans as dead-end hosts harboring L3 larvae (Despommier 2003).
Route of infection. Ingestion of embryonated eggs in food, water, fomites contaminated with canid feces (Despommier 2003).
Site in human host. Disseminated infection; common sites of infection are liver, eye, CNS, and lungs (Despommier 2003).
Toxocaracati Schrank, 1788
Toxocaramystax (Zeder, 1800)
Geographic distribution. Worldwide (Despommier 2003).
Natural hosts. Wild and domestic felids. Zoonotic in humans as dead-end hosts harboring L3 larvae (Despommier 2003).
Route of infection. Ingestion of embryonated eggs in food, water, fomites contaminated with felid feces (Despommier 2003).
Site in human host. Disseminated infection; common sites of infection are liver, eye, CNS, and lungs (Despommier 2003).
●●●●●●●● Oxyurida Weinland, 1858
●●●●●●●●● Oxyuridae Cobbold, 1864
Genus Enterobius Baird, 1853
Enterobiusvermicularis (Linnaeus, 1758)
Enterobiusgregorii Hugot, 1983
Geographic distribution. Worldwide (Wendt et al. 2019).
Natural hosts. Humans (Wendt et al. 2019).
Route of infection. Ingestion of embryonated eggs on contaminated fomites (Wendt et al. 2019).
Site in human host. Cecum, large intestine, appendix; ectopic colonization of female urogenital tract (Wendt et al. 2019).
Genus Syphacia Seurat, 1916
Syphaciaoblevata (Rudolphi, 1802)
Geographic distribution. Worldwide (Riley 1919).
Natural hosts. Rodents (Riley 1919).
Route of infection. Presumed ingestion of embryonated eggs on contaminated fomites (Riley 1919).
Site in human host. Large intestine (Riley 1919).
●●●●●●●● Spirudida De Ley & Blaxter, 2002
●●●●●●●●● Filarioidea Chabaoud & Anderson, 1959
●●●●●●●●●● Onchocercidae Chabaud & Anderson, 1959
Genus Acanthocheilonema Cobbold, 1870
Acanthocheilonemareconditum (Grassi, 1889)
Geographic distribution. Worldwide (Otranto and Eberhard 2011).
Natural hosts. Vector intermediate hosts are fleas and lice, primarily the cat flea (Ctenocephalidesfelis). Definitive hosts are canids. Zoonotic in humans (Otranto and Eberhard 2011).
Route of infection. Introduction of L3 larvae via the bite of an infected flea (Otranto and Eberhard 2011).
Site in human host. Eyes (Huynh et al. 2001; Otranto and Eberhard 2011).
Notes. Several cases of Acanthocheilonema-like nematodes recovered from human eyes have been reported, though not identified further (Otranto and Eberhard 2011).
Genus Breinlia Yorke & Maplestone, 1926
Breinliaannulipapillata (Johnston & Mawson, 1938)
Geographic distribution. Australia (Koehler et al. 2021).
Natural hosts. Vector intermediate hosts are mosquitoes, although the full range of competent genera is not known. Definitive hosts are kangaroos and wallabies. Zoonotic in humans (Koehler et al. 2021).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Koehler et al. 2021).
Site in human host. Eye (Koehler et al. 2021).
Genus Brugia Buckley, 1960
Brugiamalayi (Brug, 1927)
Geographic distribution. Southeast Asia, including Philippines, Malaysia, Indonesia, South Korea, Vietnam, India (Mak 1987; Dietrich et al. 2019).
Natural hosts. Vector intermediate hosts are mosquitoes, primarily in the genera Aedes and Mansonia. Definitive hosts are humans (Mak 1987; Dietrich et al. 2019).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Mak 1987; Dietrich et al. 2019).
Site in human host. Lymphatic system (Mak 1987; Dietrich et al. 2019).
Brugiatimori Partono et al., 1977
Geographic distribution. Lesser Sunda Archipelago, including the islands of Timor, Sumba, Lembata, Pentar, Alor (Fischer et al. 2004).
Natural hosts. Vector intermediate hosts are mosquitoes in the genus Anopheles. Definitive hosts are humans (Fischer et al. 2004; Dietrich et al. 2019).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Fischer et al. 2004; Dietrich et al. 2019).
Site in human host. Lymphatic system (Fischer et al. 2004; Dietrich et al. 2019).
Unassigned Brugia species:
American Brugia spp.
Geographic distribution. North, Central, and South America (Orihel and Eberhard 1998).
Natural hosts. Unknown. Vector intermediate hosts are presumed to be mosquitoes. Possible definitive hosts include raccoons, rabbits, and felids. Presumed zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Lymphatic system (Orihel and Eberhard 1998).
Notes. Several cases of zoonotic Brugia spp. have reported in the Americas. The precise identification of the causal agents is not known due to limited information on the morphologic features observed on histopath. Human infection in North America has been tentatively attributed to B.beaveri Ash & Little, 1964 or B.lepori Eberhard, 1984 (Orihel and Ash 1995; Orihel and Eberhard 1998).
Genus Dirofilaria Railliet & Henry, 1911
SubgenusDirofilaria Railliet & Henry, 1911
Dirofilaria (D.) immitis (Leidy, 1856)
Filariamagalhaesi Blanchard, 1896
Dirofilarianasuae Mazza, 1926
Dirofilariapongoi Vogel & Vogelsang, 1930
Dirofilarialouisianensis Faust et al., 1941
Geographic distribution. Worldwide (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are primarily wild and domestic canids. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Heart, pulmonary vessels (Orihel and Eberhard 1998).
Dirofilaria (D.) spectans Freitas & Lint, 1949
Geographic distribution. South America (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are presumed to be mosquitoes. Definitive hosts is the giant river otter (Pteronurabrasiliensis). Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Digital artery (Orihel and Eberhard 1998).
Notes. Few features can separate D.spectans from D.immitis, thus the validity of the species and its involvement in human infections remain in question.
Subgenus Nochtiella Faust, 1937
Dirofilaria (N.) repens Railliet & Henry, 1911
Filariaconfunctivae Addario, 1885, in part
Geographic distribution. Europe, Africa, Asia (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are carnivores, primarily wild and domestic canids, also felids. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Skin; ectopic migration to the eye (Orihel and Eberhard 1998).
Dirofilaria (N.) striata (Molin, 1858)
Geographic distribution. North, Central, and South America (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are wild felids. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Eye (Orihel and Eberhard 1998).
Dirofilaria (N.) subdermata (Monnig, 1924)
Geographic distribution. North America (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are porcupines. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Skin (Orihel and Eberhard 1998).
Notes. Features available in transverse histologic sections are unable to reliably distinguish D.subdermata from D.ursi; therefore, specimens recovered from human cases are generally reported as “D.ursi-like”.
Dirofilaria (N.) tenuis Chandler, 1942
Filariaconfunctivae Addario, 1885, in part
Geographic distribution. North America (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are primarily raccoons. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Skin; ectopic migration to the eyes (Orihel and Eberhard 1998).
Dirofilaria (N.) ursi Yamaguti, 1941
Geographic distribution. North America, Russia, Japan (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are black flies in the genus Simulium. Definitive hosts are bears. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Orihel and Eberhard 1998).
Site in human host. Skin (Orihel and Eberhard 1998).
Notes. Features available in transverse histologic sections are unable to reliably distinguish D.subdermata from D.ursi; therefore, specimens recovered from human cases are generally reported as “D.ursi-like”.
Dirofilaria , incertae sedis:
Dirofilaria sp. Genotype Hong Kong
Dirofilariahongkongensis To et al., 2012
Geographic distribution. Southeast Asia (Dantas-Torres and Otranto 2020; To et al. 2012).
Natural hosts. Vector intermediate hosts are unknown. Definitive hosts are canids. Zoonotic in humans (To et al. 2012; Dantas-Torres and Otranto 2020).
Route of infection. Presumably via the introduction of L3 larvae via the bite of an infected vector.
Site in human host. Skin (To et al. 2012; Dantas-Torres and Otranto 2020).
Notes.Dirofilariahonkongensis was described from dogs and humans in Hong Kong based on molecular characterization (To et al. 2012). The species was not described under the criteria of the ICZN and no type specimen was designated. To complicate matters, they described the species as ‘CandidatusDirofilariahonkongensis’. The term candidatus is not used in zoological nomenclature and is usually only used for bacteria and other organisms that cannot be cultured. The species should be considered nomen nudum (Mathison and Pritt 2019; Dantas-Torres and Otranto 2020).
Genus Dunnifilaria Mullin & Balastingam, 1973
Geographic distribution. Mexico, Southeast Asia (Lam et al. 2010).
Natural hosts. Vector intermediate hosts are unknown. Definitive hosts are rodents. Zoonotic in humans (Lam et al. 2010).
Route of Infection. Presumed introduction of L3 larvae via the bite of an infected vector.
Site in human host. Eye (Lam et al. 2010).
Notes. The single human case was reported from the eye of a patient in Malaysia (Lam et al. 2010). The worm was not identified at the species level but was reported as being most consistent with D.ramachandrani Mullin & Balasingam, 1973, a parasite of the long-tailed giant rat in Malaysia.
Genus Loa Stiles, 1905
Loaloa (Cobbold, 1864)
Geographic distribution. West-central Africa (Whittaker et al. 2018).
Natural hosts. Vector intermediate hosts are deer flies in the genus Chrysops. Definitive hosts are humans (Whittaker et al. 2018).
Route of infection. Introduction of L3 larvae via the bite of an infected deer fly (Whittaker et al. 2018).
Site in human host. Skin; ectopic migration to the eyes (Whittaker et al. 2018).
Notes. Cases of L.loa in non-travelers outside of endemic areas should be considered as possible misidentifications. There are many case reports of L.loa from India, many of which appear to represent misidentifications of Dirofilaria (prob. D.repens).
Genus Mansonella Faust, 1929
Mansonellaozzardi Manson, 1897
Geographic distribution. Central and South America, Caribbean (Lima et al. 2016).
Natural hosts. Vector intermediate hosts are biting midges (genus Culicoides) and black flies (genus Simulium). Definitive hosts are humans (Lima et al. 2016).
Route of infection. Introduction of L3 larvae via the bite of an infected arthropod vector (Lima et al. 2016).
Site in human host. Skin (Lima et al. 2016).
Mansonellaperstans (Manson, 1891)
Dipetalonemaberghei Chardome & Peel, 1951
Geographic distribution. Africa, South America, Caribbean (Mediannikov and Ranque 2018).
Natural hosts. Vector intermediate hosts are biting midges in the genus Culicoides. Definitive hosts are humans (Mediannikov and Ranque 2018).
Route of infection. Introduction of L3 larvae via the bite of an infected Culicoides biting midge (Mediannikov and Ranque 2018).
Site in human host. Peritoneal cavity, pleural cavity, pericardium, mesenteries (Mediannikov and Ranque 2018).
Mansonellastreptocerca (MacFie & Corson, 1922)
Geographic distribution. Sub-Saharan Africa (Mediannikov and Ranque 2018).
Natural hosts. Vector intermediate hosts are biting midges in the genus Culicoides. Definitive hosts are humans, non-human primates (Mediannikov and Ranque 2018).
Route of infection. Introduction of L3 larvae via the bite of an infected Culicoides biting midge (Mediannikov and Ranque 2018).
Site in human host. Skin (Mediannikov and Ranque 2018).
Genus Meningonema Orihel & Esslinger, 1973
Meningonemaperuzzii Orihel & Esslinger, 1973
Geographic distribution. Africa (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are unknown. Definitive hosts are monkeys. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected arthropod vector (Orihel and Eberhard 1998).
Site in human host. CNS (Orihel and Eberhard 1998).
Genus Molinema Freitas & Lint, 1939
Geographic distribution. North, Central, and South America (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts are mosquitoes. Definitive hosts are rodents. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Orihel and Eberhard 1998).
Site in human host. Eyes (Orihel and Eberhard 1998).
Notes. Human cases of Molinema are rare. Cases from the northwestern United States are believed to be attributed to either M.arbuta (Highby, 1943), a parasite of porcupines, or M.sprenti (Anderson, 1953), a parasites of beaver (Orihel and Eberhard 1998).
Genus Onchocerca Diesing, 1841
Onchocercacervicalis Railliet & Henry, 1910
Geographic distribution. Worldwide (Cambra-Pellejà et al. 2020; Papini et al. 2020).
Natural hosts. Vector intermediate hosts are biting midges in the genus Culicoides. Definitive hosts are horses and other equids. Zoonotic in humans (Cambra-Pellejà et al. 2020; Papini et al. 2020).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Orihel and Eberhard 1998).
Site in human host. Skin, eyes (Burr et al. 1998; Lai et al. 2014).
Onchocercadewitteijaponica Uni et al., 2001
Geographic distribution. Japan (Uni et al. 2015, 2017).
Natural hosts. Vector intermediate hosts are black flies in the genus Simulium. Definitive hosts are wild pigs. Zoonotic in humans (Uni et al. 2015, 2017).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Uni et al. 2015, 2017).
Site in human host. Skin (Uni et al. 2015, 2017).
Onchocercagutturosa (Neumann, 1919)
Geographic distribution. Africa, Europe, Asia, Australia (Cambra-Pellejà et al. 2020).
Natural hosts. Vector intermediate hosts are biting midges in the genus Culicoides. Definitive hosts are cattle. Zoonotic in humans (Cambra-Pellejà et al. 2020).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Cambra-Pellejà et al. 2020).
Site in human host. Skin (Lai et al. 2014).
Onchocercajakutensis (Gubanov, 1964)
Geographic distribution. Europe, Asia (Cambra-Pellejà et al. 2020).
Natural hosts. Vector intermediate hosts are black flies in the genus Simulium. Definitive hosts are deer. Zoonotic in humans (Cambra-Pellejà et al. 2020).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Cambra-Pellejà et al. 2020).
Site in human host. Skin, eyes (Koehsler et al. 2007).
Onchocercalupi Rodonaja, 1967
Geographic distribution. Europe, Asia, North America (Cantey et al. 2016).
Natural hosts. Putative vector intermediate hosts are black flies in the genus Simulium. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans (Cantey et al. 2016).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Cantey et al. 2016).
Site in human host. Skin, skeletal muscle, cervical nodules (Cantey et al. 2016).
Onchocercavolvulus (Leuckart, 1893)
Geographic distribution. Sub-Saharan Africa, Yemen, Central and South America (Udall 2007).
Natural hosts. Vector intermediate hosts are black flies in the genus Simulium. Definitive hosts are humans (Udall 2007).
Route of infection. Introduction of L3 larvae via the bite of an infected black fly (Udall 2007).
Site in human host. Skin, subcutaneous nodules (Udall 2007).
Genus Pelecitus Railliet & Henry, 1910
Geographic distribution. Worldwide (Bain et al. 2011).
Natural hosts. Vector intermediate hosts are various avian live, mosquitoes, and tabanid flies. Definitive hosts are birds, lagomorphs, and marsupials. Zoonotic in humans (Bain et al. 2011).
Route of infection. Introduction of L3 larva via the bite of an infected mosquito (Bain et al. 2011).
Site in human host. Eyes (Bain et al. 2011).
Notes. The single case of human infection with Pelecitus was from Brazil and was not identified to the species level (Bain et al. 2011).
Genus Wuchereria Da Silva Araujo, 1877
Wuchereriabancrofti (Cobbold, 1877)
Wuchereriapacifica Manson-Bahr, 1941
Geographic distribution. Circumtropical, including South America, Caribbean, Africa, Asia, and Pacific Islands (Mak 1987; Dietrich et al. 2019).
Natural hosts. Vector intermediate hosts are mosquitoes, including the genera Aedes, Anopheles, and Culex. Definitive hosts are humans (Mak 1987; Dietrich et al. 2019).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Mak 1987; Dietrich et al. 2019).
Site in human host. Lymphatic system (Mak 1987; Dietrich et al. 2019).
●●●●●●●●●● Setariidae Skrjabin & Shikhobalova, 1945
Genus Setaria Viborg, 1795
Setariaequina (Abildgaard, 1789)
Geographic distribution. Worldwide (Nabie et al. 2017).
Natural hosts. Vector intermediate hosts are believed to be mosquitoes in the genera Aedes or Culex. Definitive hosts are horses and other equids. Zoonotic in humans (Nabie et al. 2017).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Nabie et al. 2017).
Site in human host. Eyes (Nabie et al. 2017).
Setarialabiatopapillosa (Allessandrini, 1838)
Geographic distribution. Worldwide (Panaitescu et al. 1999).
Natural hosts. Vector intermediate hosts are believed to be mosquitoes in the genus Aedes. Definitive hosts are bovids. Zoonotic in humans (Panaitescu et al. 1999).
Route of infection. Introduction of L3 larvae via the bite of an infected mosquito (Panaitescu et al. 1999).
Site in human host. Eyes (Panaitescu et al. 1999).
Filaroidea, incertae sedis:
“Microfilaria” bolivarensis (Godoy et al., 1980)
Geographic distribution. Venezuela (Orihel and Eberhard 1998).
Natural hosts. Unknown; presumed to be zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Presumed introduction of L3 larvae via the bite of an infected arthropod vector.
Site in human host. Unknown, only described from microfilariae in blood (Orihel and Eberhard 1998).
“Microfilaria” rodhaini (Peel & Chardome, 1946)
Geographic distribution. Gabon (Orihel and Eberhard 1998).
Natural hosts. Vector intermediate hosts unknown. Definitive hosts presumed to be bonobos and chimpanzees. Zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Presumed introduction of L3 larvae via the bite of an infected arthropod vector
Site in human host. Unknown, only described from microfilariae in blood (Orihel and Eberhard 1998).
“Microfilaria” semiclarum (Fain, 1974)
Geographic distribution. Democratic Republic of Congo (Orihel and Eberhard 1998).
Natural hosts. Unknown; presumed to be zoonotic in humans (Orihel and Eberhard 1998).
Route of infection. Presumed introduction of L3 larvae via the bite of an infected arthropod vector.
Site in human host. Unknown, only described from microfilariae in blood (Orihel and Eberhard 1998).
●●●●●●●●●● Spiruroidea Oerley, 1885
●●●●●●●●●●● Gongylonematidae Sobolev, 1949
Genus Gongylonema Molin, 1857
Gongylonemapulchrum Molin, 1857
Geographic distribution. Worldwide (Libertin et al. 2017).
Natural hosts. Intermediate hosts are insects, primarily coprophagous beetles and cockroaches. Definitive hosts are mammals, including ruminants, carnivores, insectivores, lagomorphs. Zoonotic in humans (Libertin et al. 2017).
Route of infection. Ingestion of L3 larvae in infected insects (Libertin et al. 2017).
Site in human host. Oral mucosa (Libertin et al. 2017).
●●●●●●●●●●● Gnathostomatidae Railliet, 1895
Genus Gnathostoma Owen, 1837
Gnathostomabinucleatum (Almeyda-Artigas, 1991)
Geographic distribution. Central and South America (Cornaglia et al. 2016).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish, amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are wild and domestic felids and canids. Zoonotic in humans as dead-end hosts harboring L3 larvae (Cornaglia et al. 2016).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Cornaglia et al. 2016).
Site in human host. Skin, heart, intestinal tract, ears, eyes, CNS (Cornaglia et al. 2016).
Gnathostomadoloresi (Tubangui, 1925)
Geographic distribution. Southeast Asia, Japan (Herman and Chiodini 2009).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish. Amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are wild and domestic pigs. Zoonotic in humans as dead-end hosts harboring L3 larvae (Herman and Chiodini 2009).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Herman and Chiodini 2009).
Site in human host. Skin, heart, intestinal tract, ears, eyes, CNS (Herman and Chiodini 2009).
Gnathostomahispidum (Fedtschenko, 1872)
Geographic distribution. Southeast Asia, India, Australia (Herman and Chiodini 2009).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish. Amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are wild and domestic pigs. Zoonotic in humans as dead-end hosts harboring L3 larvae (Herman and Chiodini 2009).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Herman and Chiodini 2009).
Site in human host. Skin, heart, intestinal tract, ears, eyes, CNS (Herman and Chiodini 2009).
Gnathostomamalaysiae (Miyazaki & Dunn, 1965)
Geographic distribution. Southeast Asia (Nomura et al. 2000).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish. Amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are rodents, including rats. Zoonotic in humans as dead-end hosts harboring L3 larvae (Nomura et al. 2000).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Nomura et al. 2000).
Site in human host. Skin (Nomura et al. 2000).
Notes. The single case report of G.malaysiae in humans was reported from two Japanese fisherman who described eating raw freshwater shrimp in Myanmar. The species-level identification was considered presumptive (Nomura et al. 2000).
Gnathostomanipponicum Yamaguti, 1941
Geographic distribution. Japan, Korea, China (Herman and Chiodini 2009).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish. Amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are weasels and minks. Zoonotic in humans as dead-end hosts harboring L3 larvae (Herman and Chiodini 2009).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Herman and Chiodini 2009).
Site in human host. Skin, heart, intestinal tract, ears, eyes, CNS (Herman and Chiodini 2009).
Gnathostomaspinigerum Levinsen, 1889
Geographic distribution. Southeast Asia, southern Africa, Madagascar, Australia (Herman and Chiodini 2009).
Natural hosts. First intermediate hosts are freshwater copepods. Second intermediate hosts are freshwater fish. Amphibians, birds, rodents, and reptiles can serve as paratenic hosts. Definitive hosts are wild and domestic canids and felids. Zoonotic in humans as dead-end hosts harboring L3 larvae (Herman and Chiodini 2009).
Route of infection. Ingestion of L3 larvae in infected intermediate or paratenic hosts (Herman and Chiodini 2009).
Site in human host. Skin, heart, intestinal tract, ears, eyes, CNS (Herman and Chiodini 2009).
●●●●●●●●●● Camallanida Travassos, 1920
●●●●●●●●●●● Dracunculidae Stiles, 1907
Genus Dracunculus Reichard, 1759
Dracunculusmedinensis (Linnaeus, 1758)
Geographic distribution. Focal areas in sub-Saharan Africa, including Chad, Angola, and South Sudan (Eberhard et al. 2014b; Hopkins et al. 2020).
Natural hosts. Intermediate hosts are freshwater copepods; freshwater fish and amphibians can serve as paratenic or transport hosts. Definitive hosts are humans; canids, felids, and non-human primates can serve as reservoir hosts (Eberhard et al. 2014b; Hopkins et al. 2020).
Route of infection. Ingestion of L3 larvae in infected copepods or paratenic hosts (Eberhard et al. 2014b; Hopkins et al. 2020).
Site in human host. Subcutaneous tissues (Eberhard et al. 2014b; Hopkins et al. 2020).
Notes. Reports of D.medinensis infections acquired outside of historically endemic zones and/or in zones where eradication has been well-established are highly likely to represent misidentifications with other nematodes. In limited instances, these represent genuine infections with other unknown Dracunculus spp. (Kobayashi et al. 1986).
Dracunculus sp.
Geographic distribution. Vietnam (Thach et al. 2021).
Natural hosts. Unknown; presumed zoonotic in humans (Thach et al. 2021).
Route of infection. Unknown; presumed ingestion of intermediate or reservoir host.
Site in human host. Subcutaneous abscesses (Thach et al. 2021).
Notes. There is a single report of human infection with a non-medinensisDracunculus species from Vietnam. Genetically it is most similar to D.insignis (Leidy, 1858) and D.lutrae Crichton et Beverley-Burton, 1973, parasites of carnivores (Thach et al. 2021).
Spiruroidea, incertae sedis:
Spirurina Type X
Geographic distribution. Japan (Goto et al. 1998; Makino et al. 2014).
Natural hosts. Intermediate or paratenic hosts are marine squid and fish. Definitive hosts unknown. Zoonotic in humans (Goto et al. 1998; Makino et al. 2014).
Route of infection. Presumed ingestion of L3 larvae in undercooked squid or fish (Goto et al. 1998; Makino et al. 2014).
Site in human host. Skin, eyes, ileum (Goto et al. 1998; Makino et al. 2014).
Notes. Around 50 infections with Spirurina type X larvae have been identified in humans who have consumed various seafood items, particularly small squid species. Molecular studies tentatively identified similar type X larvae as those of Crassicaudagiliakiana Skrjaban & Andreeva, 1934, a nematode of Baird’s beaked whale (Berardiusbairdii) (Sugiyama et al. 2007).
●●●●●●●●●● Thelazioidea Skrjabin, 1915
●●●●●●●●●●● Thelaziidae Skrjabin, 1915
Genus Oxyspirura Dräsche in Stossich, 1897
Geographic distribution. Worldwide (Dung et al. 2020).
Natural hosts. Intermediate hosts are arthropods. Definitive hosts are birds and non-human primates. Zoonotic in humans as dead-end hosts harboring L3 larvae (Dung et al. 2020).
Route of Infection. Ingestion of infected arthropod intermediate host (Dung et al. 2020).
Site in human host. Skin (Dung et al. 2020).
Notes.Oxyspirura has been reported as a cause of pruritic cutaneous larval migrans in a patient in Vietnam, but the specimen was not characterized at the species level (Dung et al. 2020).
Genus Rictularia Froelich, 1802
Geographic distribution. Worldwide (Kenney et al. 1975).
Natural hosts. Arthropods are intermediate hosts. A wide range of mammals serve as definitive hosts. Zoonotic in humans (Kenney et al. 1975).
Route of infection. Presumed ingestion of L3 larvae in infected intermediate hosts.
Site in human host. Appendix (Kenney et al. 1975).
Notes. The single human case of infection with Rictularia was reported from a patient in New York postmortem (Kenney et al. 1975).
Genus Thelazia Bosc in Blainville 1819
Thelaziacaliforniensis Price, 1930
Geographic distribution. Western North America (Bradbury et al. 2018).
Natural hosts. Vector intermediate hosts are flies in the genus Fannia. Definitive hosts are mammals, including wild and domestic carnivores, deer, sheep, and lagomorphs. Zoonotic in humans (Bradbury et al. 2018).
Route of infection. Deposition of L3 larvae on the eye by vector fly (Bradbury et al. 2018).
Site in human host. Eye (Bradbury et al. 2018).
Thelaziacallipaeda Railliet & Henry, 1910
Geographic distribution. Europe, Asia (Otranto and Dutto 2008; Sah et al. 2018).
Natural hosts. Vector intermediate hosts are flies in the families Drosophilidae, primarily the genus Phortica. Definitive hosts are mammals, primarily carnivores and lagomorphs. Zoonotic in humans (Otranto and Dutto 2008; Sah et al. 2018).
Route of infection. Deposition of L3 larvae on the eye by vector fly (Otranto and Dutto 2008; Sah et al. 2018).
Site in human host. Eye (Otranto and Dutto 2008; Sah et al. 2018).
Thelaziagulosa (Railliet & Henry, 1910)
Geographic distribution. North America, Europe, Central Asia, Australia (Bradbury et al. 2018; Bradbury et al. 2019a).
Natural hosts. Vector intermediate hosts are muscid flies in the genus Musca. Definitive hosts are ungulates, primarily cattle. Zoonotic in humans (Bradbury et al. 2018; Bradbury et al. 2019a).
Route of infection. Deposition of L3 larvae on the eye by vector fly (Bradbury et al. 2018; Bradbury et al. 2019a).
Site in human host. Eye (Bradbury et al. 2018; Bradbury et al. 2019a).
●●●●●●●●● Physalopteroidea Railliet, 1893
●●●●●●●●●● Physalopteridae Railliet, 1893
Genus Physaloptera Rudolfi, 1819
Physalopteracaucasica (von Linstow, 1902)
Geographic distribution. Africa, Asia (Vandepitte et al. 1964; Makki et al. 2017).
Natural hosts. Intermediate hosts are insects, especially crickets, cockroaches, and beetles. Definitive hosts are non-human primates. Zoonotic in humans (Vandepitte et al. 1964; Makki et al. 2017).
Route of infection. Presumed ingestion of L3 larvae in infected insects (Vandepitte et al. 1964; Makki et al. 2017).
Site in human host. Gastrointestinal tract (Vandepitte et al. 1964; Makki et al. 2017).
Notes. This species is often placed in the genus Abbreviata Travassos, 1926. Eggs consistent with Physaloptera spp. have been recovered from human coprolites in archaeological sites across the world, but species identity has not been established in paleoparasitological cases (Makki et al. 2017).
●●●●●●● Rhabditina Chitwood, 1933
●●●●●●●● Rhabditida Orley, 1880
●●●●●●●●● Rhabditidae Orley, 1880
Genus Diploscapter Cobb, 1913
Diploscaptercoronata (Cobb, 1893)
Geographic distribution. Worldwide (Morimoto et al. 2006; Chandler 2009).
Natural hosts. None (environmental); humans are incidental hosts (Morimoto et al. 2006; Chandler 2009).
Route of infection. Unknown, presumed ingestion of L3 larvae on contaminated produce (Morimoto et al. 2006; Chandler 2009).
Site in human host. Gastrointestinal tract (Morimoto et al. 2006; Chandler 2009).
Genus Halicephalobus Timm, 1956
Halicephalobusgingivalis (Stephanski, 1954)
Micronemadeletrix Anderson & Bemrick, 1965
Geographic distribution. Worldwide (Onyiche et al. 2018).
Natural hosts. None (environmental); humans are incidental hosts (Onyiche et al. 2018).
Route of infection. Unknown, presumed inoculation of L3 larvae into wounds or mucus membranes; organ transplantation (Onyiche et al. 2018).
Site in human host. Disseminated infection with predilection for CNS (Papadi et al. 2013; Onyiche et al. 2018).
Genus Pelodera Schneider, 1866
Peloderastrongyloides (Schneider, 1860)
Geographic distribution. Worldwide (Saari and Nikander 2006).
Natural hosts. None (environmental); humans are incidental hosts (Saari and Nikander 2006).
Route of infection. Unknown, presumed direct penetration of skin by L3 larvae or possibly inoculation into wounds (Saari and Nikander 2006).
Site in human host. Skin (Orihel and Ash 1995).
Genus Rhabditis Dujardin, 1845
Geographic distribution. Worldwide (Fadaei Tehrani et al. 2019).
Natural hosts. None (environmental); humans are incidental hosts (Fadaei Tehrani et al. 2019).
Route of infection. Unknown, presumed inoculation of L3 larvae into wounds or mucus membranes (Fadaei Tehrani et al. 2019).
Site in human host. Small intestine, urogenital tract, ear (Teschner et al. 2014; Fadaei Tehrani et al. 2019).
Notes. Human cases of Rhabditis are not usually characterized at the species level. There have been cases specifically attributed to R.axei (Cobbold, 1884) from China (Yu et al. 2019), Iran (Meamar et al. 2007), and Zimbabwe (Goldsmid 1967) and R.hominis Kobayashi, 1920 from Japan and the United States (Sandground 1925). It is not always clear which cases represent true infection versus environmental contamination of clinical specimens (Sandground 1925).
●●●●●●●●● Strongyloididae Chitwood & McIntosh, 1934
Genus Strongyloides Grassi, 1879
Strongyloidesfuellbornifuellborni von Linstow, 1905
Geographic distribution. Africa, Southeast Asia (Viney et al. 1991; Barratt et al. 2019).
Natural hosts. Non-human primates. Zoonotic in humans (Viney et al. 1991; Barratt et al. 2019).
Route of infection. Penetration of the skin by L3 larvae (Viney et al. 1991; Barratt et al. 2019).
Site in human host. Small intestine, disseminated infection in immunocompromised hosts, including to the lung, skin, kidneys, and brain (Viney et al. 1991; Barratt et al. 2019).
Strongyloidesfuellbornikellyi Viney et al., 1991
Geographic distribution. Papua New Guinea (Viney et al. 1991; Barratt et al. 2019).
Natural hosts. Non-human primates. Zoonotic in humans (Viney et al. 1991; Barratt et al. 2019).
Route of infection. Penetration of the skin by L3 larvae (Viney et al. 1991; Barratt et al. 2019).
Site in human host. Small intestine, disseminated infection in immunocompromised hosts, including to the lung, skin, kidneys, and brain (Viney et al. 1991; Barratt et al. 2019).
Strongyloidesmyopotami Artigas & Pacheco, 1933
Geographic distribution. South America, North America, Europe, Africa, Asia (Choe et al. 2014).
Natural hosts. Nutria. Zoonotic in humans as a dead-end host (Choe et al. 2014).
Route of infection. Penetration of skin by L3 larvae (Choe et al. 2014).
Site in human host. Skin (Choe et al. 2014).
Notes.Strongyloidesmyopotami causes a short-lived dermatologic reaction in human skin, commonly referred to as ‘nutria itch’ or ‘marsh itch’. The parasite cannot survive in the human host and does not migrate beyond the dermis (Choe et al. 2014). Experimental evidence suggests the possibility of fleeting patent infection in humans (Little 1965).
Strongyloidesprocyonis Little, 1966
Geographic distribution. North America, Asia (Choe et al. 2014).
Natural hosts. Raccoons. Zoonotic in humans as a dead-end host (Choe et al. 2014).
Route of infection. Penetration of skin by L3 larvae (Choe et al. 2014).
Site in human host. Skin (Choe et al. 2014).
Notes.Strongyloidesprocyonis causes a short-lived dermatologic reaction in human skin, commonly referred to as ‘swimmer’s itch’ or ‘marsh itch’. The parasite cannot survive in the human host and does not migrate beyond the dermis (Choe et al. 2014).
Strongyloidesstercoralis Bavay, 1876
Geographic distribution. Worldwide (Page et al. 2018; Barratt et al. 2019).
Natural hosts. Humans; dogs may serve as reservoir hosts (Page et al. 2018; Barratt et al. 2019).
Route of infection. Penetration of the skin by L3 larvae; organ transplantation (Abanyie et al. 2015; Page et al. 2018; Barratt et al. 2019).
Site in human host. Small intestine, disseminated infection in immunocompromised hosts, including to the lung, skin, kidneys, and brain (Page et al. 2018; Barratt et al. 2019).
●●●●●●●● Strongylida Molin, 1861
●●●●●●●●● Chabertiidae Popova, 1952
Genus Oesophagostomum Molin, 1861
Oesophagostomumaculaetum (von Linstow, 1879)
Geographic distribution. Southeast Asia, Japan (Polderman and Blotkamp 1995).
Natural hosts. Non-human primates. Zoonotic in humans (Polderman and Blotkamp 1995).
Route of infection. Ingestion of L3 larvae on plants (Polderman and Blotkamp 1995).
Site in human host. Large intestine (Ghai et al. 2014; Polderman and Blotkamp 1995).
Oesophagostomumbifurcum (Creplin, 1849)
Geographic distribution. Sub-Saharan Africa (Polderman and Blotkamp 1995).
Natural hosts. Non-human primates. Zoonotic in humans (Polderman and Blotkamp 1995).
Route of infection. Ingestion of L3 larvae on plants (Polderman and Blotkamp 1995).
Site in human host. Large intestine (Polderman and Blotkamp 1995; Ghai et al. 2014).
Oesophagostomumstephanostomum Stossich, 1904
Geographic distribution. Sub-Saharan Africa, Brazil (Polderman and Blotkamp 1995).
Natural hosts. Non-human primates. Zoonotic in humans (Glen and Brooks 1985; Polderman and Blotkamp 1995).
Route of infection. Ingestion of L3 larvae on plants (Polderman and Blotkamp 1995).
Site in human host. Large intestine (Polderman and Blotkamp 1995; Ghai et al. 2014).
●●●●●●●●● Strongylidae Baird, 1853
Genus Ternidens Railliet & Henry, 1909
Ternidensdeminutus (Railliet & Henry, 1905)
Geographic distribution. Sub-Saharan Africa (Bradbury 2019).
Natural hosts. Non-human primates. Zoonotic in humans (Bradbury 2019).
Route of infection. Unknown; presumed ingestion of L3 larvae on contaminated food or fomites, or ingestion of L3 in arthropod intermediate or paratenic hosts (Bradbury 2019).
Site in human host. Large intestine (Bradbury 2019).
●●●●●●●●● Syngamidae Leiper, 1912
Genus Mammomonogamus Ryzhikovk, 1948
Mammomonogamuslaryngeus Ryzhikovk, 1948
Geographic distribution. Circumtropical (Lopes-Torres et al. 2020).
Natural hosts. Mammals, including ruminants and felids. Annelids, mollusks, and arthropods may serve as paratenic hosts. Zoonotic in humans (da Costa et al. 2005; Lopes-Torres et al. 2020).
Route of infection. Unknown, presumed to be from ingestion of embryonated eggs or larvae, or the consumption of a paratenic host (da Costa et al. 2005).
Site in human host. Bronchial tree (da Costa et al. 2005).
●●●●●●●●● Ancylostomatidae Looss, 1905
Genus Ancylostoma Dubini, 1843
Ancylostomabraziliense Gomes de Faria, 1910
Geographic distribution. Southern United States, Central and South America, southern Africa, Southeast Asia (Tekely et al. 2013).
Natural hosts. Wild and domestic canids and felids. Zoonotic in humans as a dead-end host (Tekely et al. 2013).
Route of infection. Penetration of skin by L3 larvae (Tekely et al. 2013).
Site in human host. Skin (Tekely et al. 2013).
Ancylostomacaninum (Ercolani, 1859)
Geographic distribution. Worldwide (Tekely et al. 2013; Shepherd et al. 2018).
Natural hosts. Wild and domestic canids and felids. Zoonotic in humans (Tekely et al. 2013; Shepherd et al. 2018).
Route of infection. Penetration of skin by L3 larvae (Tekely et al. 2013).
Site in human host. Skin, rarely small intestine (Tekely et al. 2013).
Ancylostomaceylanicum Looss, 1911
Geographic distribution. Southeast Asia, Australia, Middle East (Traub 2013).
Natural hosts. Wild and domestic canids and felids. Zoonotic in humans (Traub 2013).
Route of infection. Penetration of skin by L3 larvae (Traub 2013).
Site in human host. Small intestine (Traub 2013).
Ancylostomaduodenale (Dubini, 1843)
Geographic distribution. Worldwide in tropics and subtropics; host spots of endemicity for human infection are China, India, Egypt, northern Australia, Latin America (Brooker et al. 2004; Hotez et al. 2004).
Natural hosts. Mammals, including humans, dogs, cats (Brooker et al. 2004; Hotez et al. 2004).
Route of infection. Penetration of skin by L3 larvae (Brooker et al. 2004; Hotez et al. 2004).
Site in human host. Small intestine (Brooker et al. 2004; Hotez et al. 2004).
Genus Bunostomum Railliet, 1902
Bunostomumphlebotomum (Railliet, 1900)
Geographic distribution. Worldwide (Tekely et al. 2013).
Natural hosts. Bovids. Zoonotic in humans as a dead-end host (Tekely et al. 2013).
Route of infection. Penetration of skin by L3 larvae (Tekely et al. 2013).
Site in human host. Skin (Tekely et al. 2013).
Genus Necator Stiles, 1903
Necatoramericanus (Stiles, 1902)
Geographic distribution. Worldwide in tropics and subtropics; hot spots of endemicity for human infection are southern China, southern India, Southeast Asia, sub-Saharan Africa, Latin America, southeastern USA (Brooker et al. 2004; Hotez et al. 2004).
Natural hosts. Humans (Brooker et al. 2004; Hotez et al. 2004).
Route of infection. Penetration of skin by L3 larvae (Brooker et al. 2004; Hotez et al. 2004).
Site in human host. Small intestine (Brooker et al. 2004; Hotez et al. 2004).
Necatorgorillae Noda & Yamada, 1964
Geographic distribution. Sub-Saharan Africa (Kalousová et al. 2016).
Natural hosts. Gorillas, chimpanzees. Zoonotic in humans (Kalousová et al. 2016).
Route of infection. Penetration of skin by L3 larvae (Kalousová et al. 2016).
Site in human host. Small intestine (Kalousová et al. 2016).
Genus Uncinaria Frölich, 1789
Uncinariastenocephala (Railliet, 1884)
Geographic distribution. Temperate and subarctic regions of the Northern Hemisphere (Tekely et al. 2013).
Natural hosts. Carnivores, including wild and domestic canids and felids. Zoonotic in humans as a dead-end host (Tekely et al. 2013).
Route of infection. Penetration of skin by L3 larvae (Tekely et al. 2013).
Site in human host. Skin (Tekely et al. 2013).
●●●●●●●●● Trichostrongylidae Leiper, 1912
Genus Haemonchus Cobb, 1989
Haemonchuscontortus (Rudolphi, 1802)
Geographic distribution. Worldwide (Ghadirian and Arfaa 1975).
Natural hosts. Many ruminants. Zoonotic in humans (Ghadirian and Arfaa 1975).
Route of infection. Ingestion of L3 larvae on contaminated plants and produce (Ghadirian and Arfaa 1975).
Site in human host. Small intestine (Ghadirian and Arfaa 1975).
Genus Marshallagia Orloff, 1933
Marshallagiamarshalli (Ransom, 1907)
Geographic distribution. Worldwide (Ghadirian and Arfaa 1973).
Natural hosts. Many ruminants. Zoonotic in humans (Ghadirian and Arfaa 1973).
Route of infection. Ingestion of L3 larvae on contaminated plants and produce (Ghadirian and Arfaa 1973).
Site in human host. Small intestine (Ghadirian and Arfaa 1973).
Genus Nematodirus Ransom, 1907
Nematodirusabnormalis (May, 1920)
Geographic distribution. Worldwide (Ghadirian and Arfaa 1973; Bradbury 2006).
Natural hosts. Primarily sheep. Zoonotic in humans (Ghadirian and Arfaa 1973; Bradbury 2006).
Route of infection. Ingestion of L3 larvae on contaminated plants and produce (Ghadirian and Arfaa 1973; Bradbury 2006).
Site in human host. Small intestine (Ghadirian and Arfaa 1973; Bradbury 2006).
Genus Ostertagia Ransom, 1907
Ostertagiaostertagi (Stiles, 1892)
Geographic distribution. Worldwide (Ghadirian and Arfaa 1973; Anderson 1988).
Natural hosts. Primarily bovids; also sheep, goats, equids, and other ruminants. Zoonotic in humans (Ghadirian and Arfaa 1973; Anderson 1988).
Route of infection. Ingestion of L3 larvae on contaminated plants and produce (Ghadirian and Arfaa 1973).
Site in human host. Small intestine (Ghadirian and Arfaa 1973).
Genus Teladorsagia Andreeva & Satubaldin, 1953
Teladorsagiacircumcincta (Stadelman, 1894)
Geographic distribution. Temperate climates (Ashrafi et al. 2020).
Natural hosts. Primarily sheep, also goats; zoonotic in humans (Ashrafi et al. 2020).
Route of infection. Ingestion of L3 larvae on plants and produce (Ashrafi et al. 2020).
Site in human host. Small intestine (Ashrafi et al. 2020).
Genus Trichostrongylus Looss, 1905
Trichostrongylusaxei (Cobbold, 1879)
Geographic distribution. Worldwide (Sato et al. 2011).
Natural hosts. Ungulates, primarily cattle, sheep, goats, and horses. Zoonotic in humans (Sato et al. 2011).
Route of infection. Ingestion of L3 larvae on plants and produce (Cancrini et al. 1982; Sato et al. 2011).
Site in human host. Small intestine (Sato et al. 2011).
Trichostrongyluscapricola Ransom, 1907
Geographic distribution. Worldwide (Ghadirian and Arfaa 1973; Cancrini et al. 1982).
Natural hosts. Ungulates, primarily cattle, sheep, and goats. Zoonotic in humans (Ghadirian and Arfaa 1973; Cancrini et al. 1982).
Route of infection. Ingestion of L3 larvae on plants and produce (Ghadirian and Arfaa 1973; Cancrini et al. 1982).
Site in human host. Small intestine (Ghadirian and Arfaa 1973; Cancrini et al. 1982).
Trichostrongyluscolubriformis (Giles, 1892)
Geographic distribution. Worldwide; predominate in the Middle East (Sato et al. 2011).
Natural hosts. Ungulates, primarily cattle, sheep, and goats. Zoonotic in humans (Sato et al. 2011).
Route of infection. Ingestion of L3 larvae on plants and produce (Sato et al. 2011).
Site in human host. Small intestine (Sato et al. 2011).
Trichostrongyluslongispicularis Gordon, 1933
Trichostrongyluslerouxi Biocca et al., 1974
Geographic distribution. Worldwide (excluding Africa) (Ghadirian 1977).
Natural hosts. Ungulates, primarily cattle, sheep, and goats. Zoonotic in humans (Ghadirian 1977).
Route of infection. Ingestion of L3 larvae on plants and produce (Ghadirian 1977).
Site in human host. Small intestine (Ghadirian 1977).
Trichostrongylusorientalis Jimbo, 1914
Geographic distribution. Southeast Asia, Japan (Sato et al. 2011).
Natural hosts. Ungulates, including cattle, sheep, goats, and horses. Zoonotic in humans (Sato et al. 2011).
Route of infection. Ingestion of L3 larvae on plants and produce (Sato et al. 2011).
Site in human host. Small intestine (Sato et al. 2011).
Trichostrongylusvitrinus Looss, 1905
Geographic distribution. Worldwide (Ghadirian and Arfaa 1975; Cancrini et al. 1982).
Natural hosts. Ungulates, including sheep, goats. Zoonotic in humans (Ghadirian and Arfaa 1975; Cancrini et al. 1982).
Route of infection. Ingestion of L3 larvae on plants and produce (Ghadirian and Arfaa 1975; Cancrini et al. 1982).
Site in human host. Small intestine (Ghadirian and Arfaa 1975; Cancrini et al. 1982).
●●●●●●●●● Angiostrongylidae Boehm & Gebauer, 1934
Genus Angiostrongylus Kamensky, 1905
Angiostrongyluscantonensis (Chen, 1935)
Geographic distribution. Asia, South Pacific, Hawaii, Caribbean, Africa, southern United States, Central and South America (Cowie 2013).
Natural hosts. Intermediate hosts are terrestrial mollusks. Paratenic hosts include reptiles, amphibians, planarians. Definitive hosts are rodents, primarily rats (Rattus) and cotton rats (Sigmodon). Zoonotic in humans as a dead-end host harboring L4 larvae and young adults (Cowie 2013).
Route of infection. Ingestion of L3 larvae in infected mollusks or paratenic hosts (Cowie 2013).
Site in human host. CNS (Cowie 2013).
Angiostrongyluscostaricensis Morera & Cespedes, 1971
Geographic distribution. Southern United States, Central and South America (Romero-Alegria 2014).
Natural hosts. Intermediate hosts are terrestrial mollusks. Definitive hosts are rodents. Zoonotic in humans (Romero-Alegria 2014).
Route of infection. Ingestion of L3 larvae in infected mollusks or contaminated produce (Romero-Alegria 2014).
Site in human host. Mesenteric blood vessels (Romero-Alegria 2014).
Angiostrongylusmalaysiensis Bhaibulaya & Cross, 1971
Angiostrongyluscantonensis Malaysia strain
Geographic distribution. Southeast Asia (Rodpai et al. 2016).
Natural hosts. Intermediate hosts are terrestrial mollusks. Paratenic hosts include reptiles, amphibians, planarians. Definitive hosts are rodents, primarily rats. Apparently zoonotic in humans as a dead-end host harboring larvae (Rodpai et al. 2016; Watthanakulpanich et al. 2021).
Route of infection. Ingestion of L3 larvae in infected mollusks or paratenic hosts (Watthanakulpanich et al. 2021).
Site in human host. CNS (Watthanakulpanich et al. 2021).
●●●●●●●●● Metastrongylidae Leiper, 1909
Genus Metastrongylus Molin, 1861
Metastrongyluselongatus Dujardin, 1845
Strongylusapri Gmelin, 1790
Geographic distribution. Worldwide (Calvopina et al. 2016).
Natural hosts. Intermediate hosts are earthworms. Definitive hosts are wild and domestic pigs. Zoonotic in humans (Calvopina et al. 2016).
Route of infection. Presumed ingestion of L3 larvae in infected earthwormsv
Site in human host. Lungs (Calvopina et al. 2016).
Metastrongylussalmi Gedoelst, 1923
Geographic distribution. Worldwide (Calvopina et al. 2016).
Natural hosts. Wild and domestic swine are definitive hosts; one incidental infections in reported in a human (Calvopina et al. 2016).
Route of infection. Presumed ingestion of L3 larvae in infected earthworms.
Site in human host. Lungs (Calvopina et al. 2016).
Excluded species
The following genera and species have been previously reported as human parasites. They are excluded from the above checklist because it is not believed they can cause parasitic infection in the human host, are based on demonstrable misidentifications, confirmation of identification is required, or because of taxonomic changes. The organisms are listed in alphabetical order.
Agamomermis spp. Members of the genus Agamomermis are mermithid nematodes that are free-living as adults but infect insects as larvae. Human cases are believed to represent spurious passage following accidental ingestion of worms in contaminated food or water (Leon 1946; Chabaud and Lanz 1951).
Amblyommaargentinae Neumann, 1905. This Neotropical tick was recorded as a human parasite under its synonym A.testudinis (Conil, 1877) (Doss 1974), but that record is believed to be in error (Guglielmone and Robbins 2018).
Amblyommaauricularium (Conil, 1878). This Neotropical tick is a parasite of several groups of mammals and birds. Records of this species from humans are believed to represent misidentifications, primarily of A.parvum (Guglielmone and Robbins 2018).
Amblyommacalcaris Nakatsudi, 1942. This tick was described from a human in China (Nakatsudi 1942). Apparently the species was not described properly and the name is invalid (Guglielmone and Robbins 2018)
Amblyommacompressum (Macalister, 1872). This African tick species is a parasite of mammals, especially pangolins and rodents, birds, and reptiles. Records of this species from unknown locations in Africa (Theiler 1962) require confirmation (Guglielmone and Robbins 2018).
Amblyommageayi Neumann, 1899. This tick is a parasite of various mammals and birds in Central and South America. A record of this species from a human (Esser et al. 2016) is based on conflicting host data in the paper and needs to be confirmed (Guglielmone and Robbins 2018).
Amblyommahelvolum Koch, 1844. This Southeast Asian tick is primarily a parasite of reptiles, and occasionally mammals. Records of this species feeding on humans (Doss 1974) is based on an earlier publication that stated the ticks were merely crawling on humans (Audy 1960). To date, there are no records of A.helvolum feeding on humans (Guglielmone and Robbins 2018).
Amblyommamacfarlandi Kierans et al., 1973. This tick is a parasite of tortoises on the Galapagos Islands. The single record from a human (Guglielmone et al. 2006) was not confirmed as feeding on the human host and may have merely been an incidental finding (Guglielmone and Robbins 2018).
Amblyommapomposum Dönitz, 1909. This African tick is a parasite of several groups of mammals and birds. Records from humans require confirmation (Guglielmone and Robbins 2018).
Amblyommasylvaticum (De Geer, 1778). This tick is a parasite of reptiles in South Africa. Records of this species from humans are believed to represent misidentifications (Guglielmone and Robbins 2018).
Amblyommausingeri Keirans et al., 1973. This tick is a parasite of tortoises on the Galapagos Islands. The single record from a human (Guglielmone et al. 2006) was not confirmed as feeding on the human host and may have merely been an incidental finding (Guglielmone and Robbins 2018).
Amphimermiselegans (Hagmeier, 1912). Amphimermiselegans is an Asian mermithid nematode parasitic on orthopteran insects. A human case (as Mermis) reportedly recovered from urine probably represents pseudoparasitism or contamination of the toilet by the insect host (Hasegawa et al. 1996).
Androlaelapscasalis (Berlese, 1887). This laelapid mite is a predator on other mites and insects. It was reported as a cause of human dermatitis in Israel (Rosen et al. 2002). The mouthparts of A.casalis are not adapted for piercing vertebrate skin and the dermatitis in that report may have been associated with Dermanyssusgallinae, which was also reported by the authors and is a host for A.casalis. More research is needed to determine if A.casalis can bite humans and be a cause of dermatitis.
Anisopus sp. Anisopodid flies are commonly called wood gnats or window gnats. They have been implicated in intestinal and urogenital myiasis (Smith and Taylor 1966). The larvae of anisopodids breed in decaying vegetation, fermenting sap, animal manure, tree holes, mud, and sewage. Their presence in toilets, latrines, and similar should be regarded as incidental as they feed on detritus in these substrates.
Bertiellasatyri Blanchard, 1891. This cestode was originally described from orangutans. Reports from humans (Chandler 1925) are believed to represent misidentifications of B.studeri (Sapp and Bradbury 2020).
Caccobiusvulcanus (Fabricius, 1801). Caccobiusvulcanus is a Palearctic coprophagous scarab beetles that has been implicated as a cause of scarabiasis in India (as C.mutans Sharp, 1875) (Iyengar 1928). Scarabiasis is a proposed phenomenon describing the colonization of the human intestinal tract with coprophagous scarab beetles, usually based on the finding of beetles in the soiled diapers of children. There is no pathology described for parasitism by scarab beetles and the phenomenon probably represents post-defecation contamination of diapers, toilets, latrines, and similar.
Clogmiaalbipunctata (Williston, 1893). Clogmiaalbipunctata is a psychodid fly with a nearly worldwide distribution. This species has been implicated as a cause of urogenital (El-Dib et al. 2017; Farrag et al. 2019), intestinal (Tu et al. 2007; Mokhtar et al. 2016a), and nasopharyngeal (Nevill et al. 1969; Mohammed and Smith 1976) myiasis, sometimes under the name Telmatoscopusalbipuntatus. Psychodid flies reported as causative agents of urogenital and intestinal myiasis is usually due to the incidental finding of the flies in toilets, latrines, sinks, and bathtubs. The larvae of psychodid flies breed in biofilms, including in faucets and drains, giving the false impression they were shed in stool or urine. There is no evidence that psychodid fly larvae use human tissue as a nutritive source.
Crasodactyluspunctatus Guérin-Méneville, 1847. This carabid beetle was reported from the ear of two patients in Oman (misspelled as Crasydactyluspunctatus) (Bhargava and Victor 1911). This beetle is predaceous on other insects and small invertebrates and its presence in the human ear canal should be regarded as incidental.
Cryptostrongyluspulmoni. The name Cryptostrongyluspulomoni is a provisional name given to suspect helminths associated with chronic fatigue syndrome (Klapow 1999). Images depicting this ‘parasite’ appear to be synthetic fibers. There is no evidence that C.pulmoni represents an actual animal, let alone one capable of parasitizing humans.
Cyclocephalaborealis Arrow, 1911. This scarab beetle was implicated in a large-scale infestation of the ears of Boy Scouts in Pennsylvania, USA (Maddock and Fehn 1958). Cyclocephala species are phytophagous, and its presence in the human ear canal should be regarded as incidental.
Dermacentorcruentus Koch, 1844. This European tick was listed as a human parasite based on the original description (Doss 1974), but there is no indication in the original description it was observed feeding on humans (Guglielmone and Robbins 2018).
Dermacentorhalli McIntosh, 1931. This tick is a parasite of various mammals in North and Central America. Records from humans require confirmation (Guglielmone and Robbins 2018).
Dermacentortaiwanensis Sugmito, 1935. This tick is a parasite of various mammals in China, Vietnam, and Taiwan. Records of this species from humans are believed to represent misidentifications (Guglielmone and Robbins 2018).
Dibothriocephalusalascense (Rausch & Rausch, 1956). This species was originally described from a domestic dog in the Yukon-Kuskokwim Delta of Canada. A single human case of this species was reported from an Eskimo in Alaska (Rausch et al. 1967), but the record is considered doubtful (Scholz and Kuchta 2016; Waeschenbach et al. 2017).
Diphyllobothriumcameroni Rausch, 1969. This species was originally described from the Hawaiian monk seal (Neomonachusschauinslandi) and has been recorded twice from humans in Japan (Kamo H. 1986), but the records are considered doubtful (Scholz and Kuchta 2016; Waeschenbach et al. 2017).
Diphyllobothriumelegans (Krabbe, 1865). This is a parasite of seals and has been described once from a human in Japan (Kamo H. 1986), but the record is considered doubtful (Scholz and Kuchta 2016; Waeschenbach et al. 2017).
Diphyllobothriumorcini Hatsushika & Shirouzu, 1990. This species was described from killer whales. There are two records from humans from Japan (Kifune 2000; Nakazawa 1992), but those records are considered doubtful (Waeschenbach et al. 2017).
Diphyllobothriumscoticum (Rennie & Reid, 1912). This species was described from the leopard seal (Hydrurgaleptonyx) and has been recorded once from a human in Japan (Fukumoto 1988), but that record is considered doubtful (Waeschenbach et al. 2017).
Drosophilamelanogaster Meigen, 1830. This common ‘fruit fly’ has been infrequently reported as a cause of nasal and ocular myiasis (Francesconi and Lupi 2012). Larvae breed in decaying vegetation and their presence in clinical specimens should be considered incidental.
Dryomyzaformosa (Wiedemann, 1830). This dryomyzid fly was reported as a cause of gastrointestinal myiasis in a patient from Japan suffering from delusional parasitosis. Larvae were observed in fresh stool and it was speculated they represent spurious passage following accidental ingestion of the larvae (Chigusa et al. 2000). Dryomyzid larvae feed on decaying organic material and there is no evidence they use human intestinal tissue as a nutritive source.
Emysorbicularis (Linnaeus, 1758). Emysorbicularis is the Latin name of the European pond turtle. This name was used in the 23rd edition of “Manson’s Tropical Diseases” (Farrar 2014) as a species of leech that parasitizes humans. This probably represents an editorial error and may have been intended to refer to a leech that normally parasitizes the turtle.
Eristalistenax (Linnaeus, 1758). This syrphid fly is frequently implicated in causing intestinal or urogenital myiasis (Francesconi and Lupi 2012). The larvae breed in decaying organic substrates, including manure, sewage, and contaminated water. Most reported cases are from the finding of larvae in latrines, outhouses, toilets, and similar and their presence in such locations is believed to be incidental.
Euparyphium spp. Members of this genus of echinostome flukes has been recorded from humans in Laos (Toledo and Esteban 2016); however, the identity of human isolates attributed to Euparyphium should be confirmed (Chai et al. 2012).
Fanniascalaris (Fabricius, 1794). This fly was reported as a cause of urogenital myiasis in 1975 (Werner et al. 1975; Francesconi and Lupi 2012). The specimen was reportedly recovered in urine and likely represents contamination of a toilet, latrine, or the specimen itself.
Gordius spp. A number of “gordiid worms” or “horsehair worms”, including Gordius, have been recovered from humans (typically in vomitus) (Kagei et al. 1966; Uchikawa et al. 1987; Herter and Nesse 1989; Lee et al. 2003). These most likely represent spurious passage following accidental ingestion of infected arthropod hosts or worms free in the environment. The finding of such worms in toilets is usually due to the drowning of the insect host by the parasite and liberation of the parasite therefrom.
Haemaphysaliscinnabarina Koch, 1844. Records of this Brazilian tick from humans refer to H.chordeilis (Guglielmone and Robbins 2018).
Haemaphysaliskashmirensis Hoogstraal & Varma, 1962. This tick is a parasite of mammals and reptiles in India and Pakistan. Records from humans require confirmation (Guglielmone and Robbins 2018).
Haemaphysalismuhsamae Santos Dias, 1954. This tick is a parasite of birds in Africa. Records of this species from humans require confirmation due to the morphologic challenges in identifying this species (Guglielmone and Robbins 2018).
Haemaphysalisproxima Aragão, 1911. This species has been recorded from humans in Colombia. There is no formal description for this species and the name is considered nomen nudum (Guglielmone and Robbins 2018). Records of this species from humans probably pertain to H.leporispalustris (Guglielmone and Robbins 2018).
Haemaphysaliswarburtoni Nuttall, 1912. This tick is a parasite of bovids and rodents in India, Nepal, and China. Records from humans may be based on misidentifications and require confirmation (Guglielmone and Robbins 2018).
Hyalommafranchinii Tonelli-Rondelli, 1932. This tick is a parasite of mammals and reptiles in North Africa and the Middle East. Records from humans are based on misidentifications of H.excavatum and H.marginatum (Guglielmone and Robbins 2018).
Hyalommaimpressum Koch, 1844. This tick is a parasite of various mammals and birds from sub-Saharan Africa. This species has been recorded from a human in South Africa (Bedford 1927); however, H.impressum does not occur in South Africa and that record may represent a misidentification (Guglielmone and Robbins 2018).
Hyalommaplubeum (Panzer, 1795). This name is currently considered incertae sedis, and records of H.plumbeum from humans currently pertain to H.marginatum (Guglielmone and Robbins 2018).
Hermetia spp. Larvae of these soldier flies have been implicated in cases of intestinal and furuncular myiasis (Francesconi and Lupi 2012). Larvae of Hermetia spp. breed in decaying organic material, including outhouses. Their presence in clinical specimens is probably incidental and it is not believed they cause myiasis.
Ixodesaffinis Neumann, 1899. This North and Central American tick is primarily a parasite of a wide variety of mammals, including carnivores, marsupials, and ungulates. The species is difficult to identify morphologically and past records of this species from humans are believed to be misidentifications (Guglielmone and Robbins 2018).
Ixodeshumanus Koch, 1844. This species was described from a human in Brazil, however the identity of the species is not fully understood and it may be synonymous with a member of the genus Amblyomma (Guglielmone and Robbins 2018).
Ixodesjellisoni Cooley & Kohls, 1938. This is a North American tick found on rodents and carnivores. Records of this species from humans are believed to be misidentifications (Guglielmone and Robbins 2018).
Ixodeslaysanensis Wilson, 1964. This tick is a bird parasite in Hawaii. Records of this species feed in humans (Doss 1974) are based on an earlier record that reported the tick crawling, and not feeding, on humans. To date, there is no evidence I.laysanensis feeds on humans (Guglielmone and Robbins 2018).
Ixodesloricatus Neumann, 1899. This tick is a parasite of marsupials and rodents in South America. Records from humans in Brazil (Serra-Freire 2011) require confirmation and are provisionally excluded as a parasite of humans (Guglielmone and Robbins 2018).
Ixodesluciae Sénevet, 1940. This species is a Neotropical tick of various mammals, especially marsupials and rodents. The single record of this species on a human from Argentina (Ivancovich 1992) is believed to be based on a misidentification (Guglielmone and Robbins 2018).
Ixodesmolestus James, 1923. This species was described as attacking humans in the USA, but the name is currently regarded as nomen dubium (Guglielmone and Robbins 2018).
Ixodessimplex Neumann, 1906. Records of this broadly-distributed Old World tick species of bats on humans from Japan cannot be confirmed and may be based on misidentifications (Guglielmone and Robbins 2018).
Ixodestrichosuri Roberts, 1960. This tick species is a parasite of marsupials and rodents in Australia. Records of this parasite infecting humans (Russell 2001) are based on unpublished records that require confirmation. Until such time, this species is removed from the list of ticks parasitizing humans (Guglielmone and Robbins 2018).
Lasiodermaserricorne (Fabricius, 1792). Lasiodermaserricorne is a cosmopolitan pest of dried, organic materials, including tobacco, cereals and other grains, dried fruit, and dried animal products. It was been reported as cause of canthariasis in infants in China (Sun et al. 2016) and Malaysia (Mokhtar et al. 2016b). Given the beetle’s predilection for food products, and the age of the patients, this probably represents spurious passage following consumption of contaminated food.
Ligula spp.Ligula species are diphyllobothriid parasites of fish-eating birds. There are two reports from humans, initially reported under the names Diplogonophorusbrauni Leon, 1907 and Brauniajassyensis Leon, 1908. These records are believed to represent misidentifications (Scholz and Kuchta 2016).
Lophomonasblattarum Stein, 1860. There are many case reports in the literature of L.blattarum being isolated from human respiratory specimens. These all appear to be misidentifications of ciliocytophthoria, a condition whereby detached, motile epithelial cells are observed in clinical specimens (Hadziyannis et al. 2000; Li and Gao 2016). Lophomonasblattarum is a commensal in the gut of cockroaches and not a proven agent of human infection.
Maladeracastanea (Arrow, 1913). This scarab beetle was implicated in a large-scale infestation of the ears of Boy Scouts in Pennsylvania, USA (as Autosericacastanea) (Maddock and Fehn 1958). Maladera species are phytophagous, and its presence in the human ear canal should be regarded as incidental.
Melophagusovinus (Linnaeus, 1758). Commonly called the ‘sheep ked’, M.ovinus is a cosmopolitan parasite of domestic sheep (Ovusaries), as well as wild ungulates, rabbits, and wild and domestic canids. It has been reported as parasitizing humans (Zhao et al. 2018), however there is no evidence it can survive on human blood.
Muscanebulo Fabricius, 1794. This species was reported as cause of oral myiasis in India (Sharma et al. 2008). Muscanebulo is generally considered a synonym of M.curviforceps Saccà & Rivosecchi, 1956, which itself is considered a subspecies or synonym of M.domestica. Also, M.curviforceps is considered endemic to sub-Saharan Africa (Marquez and Krafsur 2002), which should preclude it from causing myiasis in India.
Muscina spp. Flies in the genus Muscina have repeatedly been reported as causing intestinal myiasis following the recovery of fly larvae in stool (Francesconi and Lupi 2012). This probably represents post-defecation contamination of the stool specimen. There is no evidence Muscina uses human tissue as a nutritive source.
Onthophagusbifasciatus (Fabricius, 1781). Onthophagusbifasciatus is a Palearctic dung beetle that has been implicated as a causative agent of scarabiasis in India (Iyengar 1928). Scarabiasis is a proposed phenomenon describing the colonization of the human intestinal tract with coprophagous scarab beetles, usually based on the finding of beetles in the soiled diapers of children. There is no pathology described for parasitism by scarab beetles and the phenomenon probably represents post-defecation contamination of diapers, toilets, latrines, and similar.
Onthophagusunifasciatus (Schaller, 1783). Onthophagusunifasciatus is a Palearctic dung beetle that has been implicated as a causative agent of scarabiasis in Sri Lanka (Iyengar 1928; Gunawardena 1963). Scarabiasis is a proposed phenomenon describing the colonization of the human intestinal tract with coprophagous scarab beetles, usually based on the finding of beetles in the soiled diapers of children. There is no pathology described for parasitism by scarab beetles and the phenomenon probably represents post-defecation contamination of diapers, toilets, latrines, and similar.
Palpodascutellaris (Fabricius, 1805). This is a species of syrphid fly from Central and northern South America. It was reported as the cause of human intestinal myiasis in Costa Rica (Pérez-Bañón et al. 2020). The larvae breed in decaying organic substrates, including manure, sewage, and contaminated water. Most reported cases are from the finding of larvae in latrines, outhouses, toilets, and similar and their presence in such locations is believed to be incidental.
Parachordodes spp. A number of “gordiid worms” or “horsehair worms”, including Parachordodes, have been recovered from humans (typically in vomitus) (Yamada et al. 2012). These most likely represent spurious passage following accidental ingestion of infected arthropod hosts or worms free in the environment. The finding of such worms in toilets is usually due to the drowning of the insect host by the parasite and liberation of the parasite therefrom.
Paragordiusvarius (Leidy, 1851). A number of “gordiid worms” or “horsehair worms”, including Paragordius, have been recovered from humans (typically in vomitus) (Ali-Khan and Ali-Khan 1977). These most likely represent spurious passage following accidental ingestion of infected arthropod hosts or worms free in the environment. The finding of such worms in toilets is usually due to the drowning of the insect host by the parasite and liberation of the parasite therefrom.
Pericoma spp.Pericoma is a genus of Psychodidae that has been implicated as a cause of urinary myiasis in India (Singla et al. 2018). Psychodid flies reported as causative agents of urogenital and intestinal myiasis is usually due to the incidental finding of the flies in toilets, latrines, sinks, and bathtubs. The larvae of psychodid flies breed in biofilms, including in faucets and drains, giving the false impression they were shed in stool or urine. There is no evidence psychodid fly larvae use human tissue as a nutritive source.
Piophilacasei (Linnaeus, 1758). This species, commonly called the ‘cheese fly’, has been infrequently reported as a cause of intestinal or urogenital myiasis (Peckenscneider et al. 1952; Saleh and el Sibae 1993). The larvae of this fly breeds in foodstuffs, and its presence in toilets and latrines should be considered incidental, probably following spurious passage of the larvae after eating infested food.
Psychodaalbipennis Zetterstedt, 1850. This psychodid has been implicated as an agent of urogenital myiasis (Francesconi and Lupi 2012; Shimpi et al. 2018). Psychodid flies reported as causative agents of urogenital and intestinal myiasis is usually due to the incidental finding of the flies in toilets, latrines, sinks, and bathtubs. The larvae of psychodid flies breed in biofilms, including in faucets and drains, giving the false impression they were shed in stool or urine. There is no evidence psychodid fly larvae use human tissue as a nutritive source.
Psychodaalternata Say, 1824. This psychodid has been implicated as an agent of urogenital myiasis (Abul Hab 2001) and has been recorded from human sputa (Scott 1964). Psychodid flies reported as causative agents of urogenital and intestinal myiasis is usually due to the incidental finding of the flies in toilets, latrines, sinks, and bathtubs. The larvae of psychodid flies breed in biofilms, including in faucets and drains, giving the false impression they were shed in stool or urine. There is no evidence psychodid fly larvae use human tissue as a nutritive source.
Psychodasexpunctata Curtis, 1839. This psychodid has been implicated as a source of gasterointestinal myiasis (Okada 1927). Psychodid flies reported as causative agents of urogenital and intestinal myiasis is usually due to the incidental finding of the flies in toilets, latrines, sinks, and bathtubs. The larvae of psychodid flies breed in biofilms, including in faucets and drains, giving the false impression they were shed in stool or urine. There is no evidence psychodid fly larvae use human tissue as a nutritive source.
Rhipicentorbicornis Nutall & Warburton, 1908. This tick is a parasite of various mammals in sub-Saharan Africa. This species was recorded as a parasite on humans (Doss 1974), however that record is based on a misunderstanding that a tick observed in a human dwelling meant it feeds on humans. To date, there are no records of R.bicornis feeding on humans (Guglielmone and Robbins 2018).
Sappiniadiploidea (Hartmann & Naegler, 1908). The first case of human infection with a member of the genus Sappinia was reported to have been caused by S.diploidea based on morphologic criteria (Gelman et al. 2001). However, molecular characterization later demonstrated the species to be S.pedata (Qvarnstrom et al. 2009).
Scaritessulcatus Olivier, 1795. Scaritessulcatus is a Palearctic ground beetle that has been implicated as a cause of genital canthariasis (Paul 2007). Scarites species are free-living predaceous beetles. Given the habits of these beetles, this case probably represents environmental contamination or possibly urethral sounding.
Scenopinus spp. Members of this genus of flies have been implicated in urogenital myiasis (Thompson et al. 1970). Larvae of Scenopinus are predators on the larvae of other insects. The presence of Scenopinus larvae in clinical specimens is probably incidental.
Trichophryapiscium Bütschli, 1899. This freshwater fish pathogen was reported was reported from sinus aspirates of a patient in Iraq (Al-Duboon and Disher 2018). Images of the suspect organism in the publication showed this to be a misidentification of ciliocytophthoria, a condition whereby detached, motile epithelial cells are observed in clinical specimens (Hadziyannis et al. 2000; Li and Gao 2016).
Tyroglyphuslongior (Gervais, 1844). This grain mite has been implicated in intestinal acariasis by the finding of mites in the stool of two patients with generalized intestinal complaints (Harold Hinman and Kampmeier 1934). The finding of these mites probably represents spurious passage after incidental ingestion of the mites in contaminated foodstuffs.
Tyroglyphusputrescentiae (Schrank, 1781). This grain and mold mite has been implicated as a cause of intestinal acariasis (Khalifa et al. 2016). The finding of these mites probably represents spurious passage after incidental ingestion of the mites in contaminated foodstuffs.
Urbanorum. The name ‘Urbanorum’ has been given to usual objects observed in stool specimens. Most cases have been reported from Central and South America (de Aguiar and Alves 2018). Generally referred to as protozoans, there does not appear to be any formal description of Urbanorum in the zoological literature and the general consensus is that these objects are nothing more than peculiar artifacts. No biochemical, ultrastructural, or genetic studies have been undertaken to confirm its status as a living organism, although the exact identity of it has not been ascertained.
Acknowledgements
The authors would like to thank Dr. Sina Adl for reviewing the manuscript prior to submission.
Disclaimer: The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention.
Citation
Mathison BA, Sapp SGH (2021) An annotated checklist of the eukaryotic parasites of humans, exclusive of fungi and algae. ZooKeys 1069: 1–313. https://doi.org/10.3897/zookeys.1069.67403
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